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INSECT ARCHITECTURE


JAMES RENNIE


LONDON: PRINTED BY W. CLOWES AND SONS, STAMFORD STREET AND CHARING
CROSS.




  INSECT ARCHITECTURE

  BY

  JAMES RENNIE

  _NEW EDITION, MUCH ENLARGED_


  BY THE REV. J. G. WOOD, M.A.
  AUTHOR OF "HOMES WITHOUT HANDS," ETC.


  WITH NEARLY TWO HUNDRED ILLUSTRATIONS.


  LONDON:
  BELL AND DALDY, YORK STREET,
  COVENT GARDEN.

  1869.




EDITOR'S PREFACE TO THE NEW EDITION.


The proprietors of this interesting work having felt that much
additional knowledge of the subject has been obtained since the book
was written, have asked me to supply characteristic examples of
Insect Architecture which were not to be found in its pages. I have
accordingly added a considerable number of such examples, in most cases
accompanied by figures drawn from the specimens described. I have not
been at liberty to alter or expunge, and am not, therefore, responsible
for any portion of the letterpress except those passages which are
enclosed in brackets [ ]. Some of the specimens from which the figures
have been drawn are in my own collection, but the greater part are to
be found in the British Museum.




CONTENTS.


                                                                     PAGE

CHAPTER I.

  Introduction                                                          1


CHAPTER II.

  Structures for Protecting Eggs                                       21
  Mason-Wasps                                                          22
  Mason-Bees                                                           38
  Mining-Bees                                                          50


CHAPTER III.

  Carpenter-Bees                                                       55
  Carpenter-Wasps                                                      62
  Upholsterer-Bees                                                     64


CHAPTER IV.

  Carder-Bees                                                          74
  Lapidary-Bees                                                        79
  Humble-Bees                                                          79
  Social-Wasps                                                         80


CHAPTER V.

  Architecture of the Hive-Bee                                        112
  Preparation of Wax                                                  115
  Propolis                                                            126
  The Building of the Cell                                            131


CHAPTER VI.

  Architecture of the Hive-Bee--_continued_.
  Form of the Cells                                                   139
  Irregularities in their Workmanship                                 148
  The Finishing of the Cells                                          154


CHAPTER VII.

  Carpentry of Tree-Hoppers                                           164
  Saw-Flies                                                           168
  Icarias                                                             176


CHAPTER VIII.

  Leaf-Rolling Caterpillars                                           181


CHAPTER IX.

  Insects Forming Habitations of Detached Leaves                      195
  Cypress-Spurge Caterpillar                                          197
  Moss-Building Caterpillar                                           199


CHAPTER X.

  Caddis-Worms and Goat-Moth                                          202
  Carpenter-Caterpillars                                              207
  Puss-Moth                                                           211
  Capricorn-Beetle                                                    215
  Oak-Bark Caterpillars                                               217


CHAPTER XI.

  Earth-Mason Caterpillars                                            219
  Ant-Lion                                                            227


CHAPTER XII.

  Clothes-Moth Caterpillars                                           235
  Tent-Making Caterpillars                                            243
  Stone-Mason Caterpillars                                            247
  Muff-Shaped Tents                                                   250
  Leaf-Mining Caterpillars                                            252
  Bark-Mining Caterpillars                                            257
  Grubs of Beetles                                                    258
  Wasp-Beetle                                                         261
  Stag-Beetle                                                         262


CHAPTER XIII.

  Structures of Grasshoppers, Crickets, and Beetles                   264
  Mole Cricket                                                        265
  Field Cricket                                                       267
  Burying Beetle                                                      269
  Dung Beetle                                                         271
  Tumble-Dung Beetle                                                  273
  Cockchafer                                                          275


CHAPTER XIV.

  Architecture of Ants                                                278
  Mason-Ants                                                          279


CHAPTER XV.

  Structures of the Wood-Ant or Pismire                               294
  Carpenter-Ants                                                      301


CHAPTER XVI.

  Structures of White Ants, or Termites                               313
  Turret-Building White Ants                                          325


CHAPTER XVII.

  Structures of Silk Spun by Caterpillars                             330
  Silkworm                                                            336
  Emperor-Moth                                                        342
  Spinning Caterpillars                                               344


CHAPTER XVIII.

  Structures of Spiders                                               366
  Nest, Webs, and Nets of Spiders                                     383
  Diving Water-Spider                                                 393


CHAPTER XIX.

  Structures of Gall-Flies and Aphides                                398
  Hawthorn Weevil                                                     413
  Gall-Beetles                                                        415
  Leaf-Rolling Aphides                                                418
  Pseudo-Galls                                                        421


CHAPTER XX.

  Animal Galls, Produced by Breeze-Flies and Snail-Beetles            424
  Grub Parasite in the Snail                                          436




ILLUSTRATIONS.


                                                                     PAGE

    1.  Eggs of Insects, magnified                                     16
    2.  Larvae                                                          17
    3.  Pupae                                                           18
    4.  Insects in the Imago or perfect state                          19
    5.  Mason-Wasp                                                     23
    6.  Jaws of Mason-Wasp                                             24
    7.  Cuckoo-Fly                                                     25
    8.  Mason-Wasp's Nest and Cocoons                                  25
    9.  Mason-Wasp                                                     25
   10.  Nests, &c., of Mason-Wasps                                     26
   11.  Towers built by Mason-Wasp                                     29
   12.  Nests of _Pompilus punctum_                                    29
   13.  _Scolia Xantiana_, and section of its burrow                   35
   14.  Mason-Bee                                                      38
   15.  Exterior wall of Mason-Bee's Nest                              39
   16.  Cells of a Mason-Bee                                           39
   17.  Cells of Mason-Bees                                            46
   18.  Cells of _Chalicodoma_                                         49
   19.  Nest of _Synagris calida_                                      50
   20.  Cell of Mining-Bee                                             51
   21.  Cells of Carpenter-Bees, in an old post                        57
   22.  Carpenter-Bee and Cells                                        58
   23.  Carpenter-Wasp and Cells                                       62
   24.  Rose-leaf-cutter-Bee and Nest                                  71
   25.  Carder-Bee and Nest                                            75
   26.  Breeding-cells of Carder-Bee                                   77
   27.  Interior view of Carder-Bee's Nest                             78
   28.  Cells of Humble-Bee and Insects                                80
   29.  Nest of Common Wasp in early stage                             88
   30.  Section of Wasp's Nest                                         89
   31.  Section of Social-Wasps' Nest                                  90
   32.  Suspension-rod and part of external crust of
          Social-Wasps' Nest                                           91
   33.  Hornet's Nest in its first stage                               92
   34.  Complete Hornet's Nest, and Insect                             93
   35.  Hornet's Nest in hollow tree                                   94
   36.  Nest of Tree-Wasp                                              96
   37.  Wasp's Nest                                                    97
   38.  Wasps' Cells attached to a branch                              98
   39.  Comb of _Polistes_                                             99
   40.  Nest of the Pasteboard-maker Wasp                             103
   41.  Nest of _Myrapetra_                                           105
   42.  Nests of _Polybia_                                            108
   43.  Nests of _Synaeca_ and _Polybia_                               109
   44.  Part of a Honeycomb and Bees at work                          112
   45.  Worker-Bee, magnified                                         123
   46.  Abdomen of Wax-worker Bee                                     124
   47.  Structure of the Legs of the Bee                              130
   48.  Curtain of Wax-workers secreting wax                          133
   49.  Wax-worker laying the foundation of first cell                136
   50.  Curtain of Wax-workers                                        137
   51.  Arrangement of Cells                                          141
   52.  Foundation-wall and Cells commenced                           143
   53.  Hive-Bees and Cells                                           159
   54.  Ovipositors, with files, of Tree-hopper                       167
   55.  Excavations for eggs of Tree-hopper                           167
   56.  Ovipositor of Saw-Fly                                         169
   57.  Ovipositor of Saw-Fly, much magnified                         170
   58.  Portion of Saw-Fly's comb-toothed rasp                        171
   59.  Nest of eggs of Saw-Fly                                       173
   60.  Saw-Fly of the gooseberry                                     174
   61.  Exterior and section of Nest of _Deilocenes Ellisii_,
          and Insect                                                  176
   62.  Cells of _Icaria_                                             177
   63.  Cells of _Raphigaster Guiniensis_                             178
   64.  Single Cells of _Icaria_                                      179
   65.  Lilac-tree Moth                                               182
   66.  Nest of Lilac-leaf-roller                                     182
   67.  Do. another specimen                                          183
   68.  Small green Oak-Moth                                          184
   69.  Nests of Oak-leaf-rolling Caterpillars                        184
   70.  Nest of Nettle-leaf-rolling Caterpillar                       186
   71.  Leaf-rolling Caterpillars of the sorrel                       188
   72.  Nests of the _Hesperia Malvae_ with Caterpillar, Chrysalis,
          and Butterflies                                             189
   73.  Nest of Willow-leaf-roller                                    191
   74.  Ziczac Caterpillar and Nest                                   192
   75.  Cypress-Spurge Caterpillar                                    198
   76.  Moss-cell of small Caterpillar                                200
   77.  Leaf-nest of Caddis-Worm                                      202
   75.  Reed-nest of Caddis-Worm                                      202
   79.  Cell of _Phryganea_                                           203
   80.  Shell-nests of Caddis-Worms                                   203
   81.  Stone-nest of Caddis-Worm                                     204
   82.  Sand-nest balanced with a stone                               204
   83.  Nest of Caddis-Worm balanced with straws                      204
   84.  Various Nests of Caddis-Worms                                 206
   85.  Caterpillar of Goat-Moth                                      208
   86.  Winter-nest of Goat-Caterpillar                               208
   87.  Nest of Goat-Moth                                             209
   88.  Larva of _AEgeria_                                             211
   89.  Eggs of the Puss-Moth                                         213
   90.  Rudiments of the Cell of Puss-Moth                            213
   91.  Cell of Larva of Puss-Moth                                    214
   92.  Ichneumon                                                     215
   93.  Magnified Cells of _Pyralis strigulalis_ (?)                  217
   94.  Outside view of Nests of Earth-Mason Caterpillars             220
   95.  Nests, etc., of Earth-Mason Caterpillar                       221
   96.  Do. with perfect Moth                                         223
   97.  Nests of the Grubs of _Ephemerae_                              225
   98.  Nests of _Ephemerae_ in holes of Cossus                        225
   99.  Grub of the Ant-Lion with traps                               228
  100.  Ant-Lion's traps in experimenting-box                         231
  101.  Cases of the Clothes-Moth and Insect                          238
  102.  Transformations of the Honeycomb-Moths                        240
  103.  Transformations of the Grain-Moths                            242
  104.  Tent of Caterpillar upon elm-leaf                             244
  105.  Operations of Caterpillar upon leaf                           246
  106.  Lichen-tents and Caterpillars                                 247
  107.  Branch of willow with Caterpillars' muff-tents                251
  108.  Rose-leaf mined by Caterpillars                               253
  109.  Bramble-leaf do.                                              254
  110.  Primrose-leaf do.                                             255
  111.  Bark mined by Beetle-Grubs                                    259
  112.  Cocoons of _Rhagium_ and _Rhyncophorus_                       261
  113.  Capricorn-Beetle rounding off bark of tree                    262
  114.  _Cerambyx carcharias,_ and _Cerambyx populneus_               263
  115.  The Mole-Cricket                                              265
  116.  Nest of Mole-Cricket                                          266
  117.  _Acrida Verrucivora_ depositing her eggs                      269
  118.  Transformations of the Cockchafer                             276
  119.  Ant-hive or Formicary                                         291
  120.  Floor of Ant-nest                                             292
  121.  Insecure Nest propped up by Ants                              293
  122.  Nest of Wood-Ant                                              295
  123.  Artificial Formicary                                          298
  124.  Portion of a tree tunnelled by Jet Ants                       302
  125.  _Formica fuliginosa_                                          304
  126.  _Crematogaster_                                               310
  127.  Nests of _Polyrachis bispinosa_ and _P. textor_               311
  128.  _Termes bellicosus_ in the winged state                       317
  129.  Queen Termite distended with eggs                             320
  130.  Tree-nest of _Termites arborum_, and Hill-nests of
          _T. bellicosus_                                             324
  131.  Turret-nests of White Ants                                    326
  132.  Leg and Pro-leg of Caterpillar                                331
  133.  Caterpillar of Goat-Moth                                      332
  134.  Interior structure of Cossus                                  333
  135.  Side view and section of Silk-tube of Cossus                  334
  136.  Labium of Cossus                                              334
  137.  Cocoons of Emperor-Moth                                       343
  138.  Cocoon of _Arctia villica_                                    345
  139.  Net-work Cocoon                                               345
  140.  Nest of Puss-Moth                                             347
  141.  Caterpillars of small Ermine on Siberian crab                 351
  142.  Winter-nests of _Porthesia chrysorrhoea_                      352
  143.  Winter-nests of Social Caterpillars                           353
  144.  Pendulous Leaves                                              356
  145.  Nest of _Larrada_                                             357
  146.  Nests of _Polybia_                                            358
  147.  Nests of _Oiketicus_, &c.                                     359
  148.  Nests of _Pelopaeus_, &c.                                      361
  149.  _Bombycidae_                                                   363
  150.  Processionary Caterpillars                                    364
  151.  Nest of do.                                                   365
  152.  Garden Spider suspended by single thread                      367
  153.  Spinnerets of Spiders                                         368
  154.  Single thread of Spider, greatly magnified                    369
  155.  Attached end of Spider's thread                               369
  156.  Geometric Net of _Epeira diadema_                             387
  157.  Nest of the Mason-Spider                                      389
  158.  Nest of _Mygale sauvagesii_                                   391
  159.  Insect emerging from its Nest                                 391
  160.  Triple-clawed Foot of Spider                                  395
  161.  Small Galls on Oak-leaf                                       398
  162.  Ovipositor of Gall-Fly                                        399
  163.  Gall-Fly and mechanism of ovipositor                          400
  164.  Bedeguar Gall of the Rose                                     402
  165.  One of the bristles of Bedeguar, magnified                    403
  166.  Artichoke Gall of the Oak-bud, and Insect                     405
  167.  Leafy gall of Dyer's Broom                                    406
  168.  Semi-gall of the Hawthorn                                     408
  169.  Woolly Gall of the Oak                                        409
  170.  Oak-apple Galls                                               410
  171.  Root-galls of the Oak                                         411
  172.  Woody Gall on a Willow Branch                                 412
  173.  Currant-gall of the catkins of the Oak                        413
  174.  Gall of the Hawthorn-Weevil                                   414
  175.  Plant-Louse, magnified                                        416
  176.  Galls produced on the Poplar, and Insects                     417
  177.  Leaf of the Currant-bush with Aphides                         419
  178.  Shoot of Lime-tree contorted by _A. tiliae_                    421
  179.  Pseudo-gall of the Bramble                                    422
  180.  Pseudo-galls of the Hawthorn                                  423
  181.  Ovipositor of the Breeze-Fly                                  426
  182.  The Grub of Breeze-Fly                                        432
  183.  The Ox-Breeze-Fly                                             433
  184.  Bumps produced on cattle by Breeze-Fly                        434
  185. _Microgaster glomeratus_                                       438
  186. _Microgaster alveolarius_                                      439




INSECT ARCHITECTURE.




_CHAPTER 1._

INTRODUCTION.


It can never be too strongly impressed upon a mind anxious for the
acquisition of knowledge, that the commonest things by which we are
surrounded are deserving of minute and careful attention. The most
profound investigations of Philosophy are necessarily connected
with the ordinary circumstances of our being, and of the world in
which our every-day life is spent. With regard to our own existence,
the pulsation of the heart, the act of respiration, the voluntary
movement of our limbs, the condition of sleep, are among the most
ordinary operations of our nature; and yet how long were the wisest
of men struggling with dark and bewildering speculations before they
could offer anything like a satisfactory solution of these phenomena,
and how far are we still from an accurate and complete knowledge of
them! The science of Meteorology, which attempts to explain to us the
philosophy of matters constantly before our eyes, as dew, mist, and
rain, is dependent for its illustrations upon a knowledge of the most
complicated facts, such as the influence of heat and electricity upon
the air; and this knowledge is at present so imperfect, that even these
common occurrences of the weather, which men have been observing and
reasoning upon for ages, are by no means satisfactorily explained, or
reduced to the precision that every science should aspire to. Yet,
however difficult it may be entirely to comprehend the phenomena we
daily witness, everything in nature is full of instruction. Thus the
humblest flower of the field, although, to one whose curiosity has
not been excited, and whose understanding has, therefore, remained
uninformed, it may appear worthless and contemptible, is valuable to
the botanist, not only with regard to its place in the arrangement of
this portion of the Creator's works, but as it leads his mind forward
to the consideration of those beautiful provisions for the support of
vegetable life, which it is the part of the physiologist to study and
to admire.

This train of reasoning is peculiarly applicable to the economy of
insects. They constitute a very large and interesting part of the
animal kingdom. They are everywhere about us. The spider weaves his
curious web in our houses; the caterpillar constructs his silken cell
in our gardens; the wasp that hovers over our food has a nest not
far removed from us, which she has assisted to build with the nicest
art; the beetle that crawls across our path is also an ingenious and
laborious mechanic, and has some curious instincts to exhibit to those
who will feel an interest in watching his movements; and the moth that
eats into our clothes has something to plead for our pity, for he came,
like us, naked into the world, and he has destroyed our garments,
not in malice or wantonness, but that he may clothe himself with the
same wool which we have stripped from the sheep. An observation of
the habits of these little creatures is full of valuable lessons,
which the abundance of the examples has no tendency to diminish. The
more such observations are multiplied, the more are we led forward
to the freshest and the most delightful parts of knowledge; the more
do we learn to estimate rightly the extraordinary provisions and
most abundant resources of a creative Providence; and the better do
we appreciate our own relations with all the infinite varieties of
nature, and our dependence, in common with the ephemeron that flutters
its little hour in the summer sun, upon that Being in whose scheme
of existence the humblest as well as the highest creature has its
destined purposes. "If you speak of a stone," says St. Basil, one of
the Fathers of the Church, "if you speak of a fly, a gnat, or a bee,
your conversation will be a sort of demonstration of His power whose
hand formed them, for the wisdom of the workman is commonly perceived
in that which is of little size. He who has stretched out the heavens,
and dug up the bottom of the sea, is also He who has pierced a passage
through the sting of the bee for the ejection of its poison."

If it be granted that making discoveries is one of the most
satisfactory of human pleasures, then we may without hesitation
affirm, that the study of insects is one of the most delightful
branches of natural history, for it affords peculiar facilities for
its pursuit. These facilities are found in the almost inexhaustible
variety which insects present to the curious observer. As a proof
of the extraordinary number of insects within a limited field of
observation, Mr. Stephens informs us, that in the short space of forty
days, between the middle of June and the beginning of August, he
found, in the vicinity of Ripley, specimens of above two thousand four
hundred species of insects, exclusive of caterpillars and grubs,--a
number amounting to nearly a fourth of the insects ascertained to be
indigenous. He further tells us, that, among these specimens, although
the ground had, in former seasons, been frequently explored, there
were about one hundred species altogether new, and not before in any
collection which he had inspected, including several new genera;
while many insects reputed scarce were in considerable plenty.[A] The
localities of insects are, to a certain extent, constantly changing;
and thus the study of them has, in this circumstance, as well as in
their manifold abundance, a source of perpetual variety. Insects, also,
which are plentiful one year, frequently become scarce, or disappear
altogether, the next--a fact strikingly illustrated by the uncommon
abundance, in 1826 and 1827, of the seven-spot lady-bird (_Coccinella
septempunctata_), in the vicinity of London, though during the two
succeeding summers this insect was comparatively scarce, while the
small two-spot lady-bird (_Coccinella bipunctata_) was plentiful.

There is, perhaps, no situation in which the lover of nature and the
observer of animal life may not find opportunities for increasing his
store of facts. It is told of a state prisoner, under a cruel and
rigorous despotism, that when he was excluded from all commerce with
mankind, and was shut out from books, he took an interest and found
consolation in the visits of a spider; and there is no improbability
in the story. The operations of that persecuted creature are among the
most extraordinary exhibitions of mechanical ingenuity; and a daily
watching of the workings of its instinct would beget admiration in
a rightly-constituted mind. The poor prisoner had abundant leisure
for the speculations in which the spider's web would enchain his
understanding. We have all of us, at one period or other of our lives,
been struck with some singular evidence of contrivance in the economy
of insects, which we have seen with our own eyes. Want of leisure, and
probably want of knowledge, have prevented us from following up the
curiosity which for a moment was excited. And yet some such accident
has made men naturalists, in the highest meaning of the term. Bonnet,
evidently speaking of himself, says, "I knew a naturalist, who, when
he was seventeen years of age, having heard of the operations of the
ant-lion, began by doubting them. He had no rest till he had examined
into them: and he verified them, he admired them, he discovered new
facts, and soon became the disciple and the friend of the Pliny of
France"[B] (Reaumur). It is not the happy fortune of many to be able to
devote themselves exclusively to the study of nature, unquestionably
the most fascinating of human employments; but almost every one may
acquire sufficient knowledge to be able to derive a high gratification
from beholding the more common operations of animal life. His materials
for contemplation are always before him. Some weeks ago we made an
excursion to West Wood, near Shooter's Hill, expressly for the purpose
of observing the insects we might meet with in the wood: but we had
not got far among the bushes, when heavy rain came on. We immediately
sought shelter among the boughs of some thick underwood, composed of
oak, birch, and aspen; but we could not meet with a single insect, not
even a gnat or a fly, sheltered under the leaves. Upon looking more
narrowly, however, into the bushes which protected us, we soon found
a variety of interesting objects of study. The oak abounded in galls,
several of them quite new to us; while the leaves of the birch and
the aspen exhibited the curious serpentine paths of the minute mining
caterpillars. When we had exhausted the narrow field of observation
immediately around us, we found that we could considerably extend it,
by breaking a few of the taller branches near us, and then examining
their leaves at leisure. In this manner two hours glided quickly and
pleasantly away, by which time the rain had nearly ceased; and though
we had been disappointed in our wish to ramble through the wood, we
did not return without adding a few interesting facts to our previous
knowledge of insect economy.[C]

It will appear, then, from the preceding observations, that cabinets
and collections, though undoubtedly of the highest use, are by no
means indispensable, as the observer of nature may find inexhaustible
subjects of study in every garden and in every hedge. Nature has
been profuse enough in affording us materials for observation, when
we are prepared to look about us with that keenness of inquiry,
which curiosity, the first step in the pursuit of knowledge, will
unquestionably give. Nor shall we be disappointed in the gratification
which is thus within our reach. Were it no more, indeed, than a
source of agreeable amusement, the study of insects comes strongly
recommended to the notice of the well-educated. The pleasures of
childhood are generally supposed to be more exquisite, and to contain
less alloy, than those of riper years; and if so, it must be because
then everything appears new and dressed in fresh beauties: while in
manhood, and old age, whatever has frequently recurred begins to wear
the tarnish of decay. The study of nature affords us a succession of
"ever-new delights," such as charmed us in childhood, when everything
had the attractions of novelty and beauty; and thus the mind of the
naturalist may have its own fresh and vigorous thoughts, even while the
infirmities of age weigh down the body.

It has been objected to the study of insects, as well as to that of
Natural History in general, that it tends to withdraw the mind from
subjects of higher moment; that it cramps and narrows the range of
thought; and that it destroys, or at least weakens, the finer creations
of the fancy. Now, we should allow this objection in its fullest
extent, and even be disposed to carry it further than is usually done,
if the collecting of specimens only, or, as the French expressly
call them, chips (_echantillons_), be called a study. But the mere
collector is not, and cannot be, justly considered as a naturalist;
and, taking the term naturalist in its enlarged sense, we can adduce
some distinguished instances in opposition to the objection. Rousseau,
for example, was passionately fond of the Linnaean botany, even to the
driest minutiae of its technicalities; and yet it does not appear to
have cramped his mind, or impoverished his imagination. If Rousseau,
however, be objected to as an eccentric being, from whose pursuits no
fair inference can be drawn, we give the illustrious example of Charles
James Fox, and may add the names of our distinguished poets, Goldsmith,
Thomson, Gray, and Darwin, who were all enthusiastic naturalists. We
wish particularly to insist upon the example of Gray, because he was
very partial to the study of insects. It may be new to many of our
readers, who are familiar with the 'Elegy in a Country Churchyard,' to
be told that its author was at the pains to turn the characteristics
of the Linnaean orders of insects into Latin hexameters, the manuscript
of which is still preserved in his interleaved copy of the 'Systema
Naturae.' Further, to use the somewhat exaggerated words of Kirby and
Spence, whose work on Entomology is one of the most instructive and
pleasing books on the science, 'Aristotle among the Greeks, and Pliny
the Elder among the Romans, may be denominated the fathers of Natural
History, as well as the greatest philosophers of their day; yet both
these made insects a principal object of their attention: and in more
recent times, if we look abroad, what names greater than those of Redi,
Malpighi, Vallisnieri, Swammerdam, Leeuwenhoek, Reaumur, Linnaeus, De
Geer, Bonnet, and the Hubers? and at home, what philosophers have done
more honour to their country and to human nature than Ray, Willughby,
Lister, and Derham? Yet all these made the study of insects one of
their most favourite pursuits."[D]

And yet this study has been considered, by those who have superficially
examined the subject, as belonging to a small order of minds; and the
satire of Pope has been indiscriminately applied to all collectors,
while, in truth, it only touches those who mistake the means of
knowledge for the end:--

    "O! would the sons of men once think their eyes
    And reason given them but to study Flies!
    See Nature, in some partial, narrow shape,
    And let the Author of the whole escape;
    Learn but to trifle; or, who most observe,
    To wonder at their Maker, not to serve."[E]

Thus exclaims the Goddess of Dulness, sweeping into her net all those
who study nature in detail. But if the matter were rightly appreciated,
it would be evident that no part of the works of the Creator can be
without the deepest interest to an inquiring mind; and that a portion
of creation which exhibits such extraordinary manifestations of design
as is shown by insects must have attractions for the very highest
understanding.

An accurate knowledge of the properties of insects is of great
importance to man, merely with relation to his own comfort and
security. The injuries which they inflict upon us are extensive and
complicated; and the remedies which we attempt, by the destruction of
those creatures, both insects, birds, and quadrupeds, who keep the
ravages in check, are generally aggravations of the evil, because they
are directed by an ignorance of the economy of nature. The little
knowledge which we have of the modes by which insects may be impeded
in their destruction of much that is valuable to us, has probably
proceeded from our contempt of their individual insignificance. The
security of property has ceased to be endangered by quadrupeds of
prey, and yet our gardens are ravaged by aphides and caterpillars. It
is somewhat startling to affirm that the condition of the human race
is seriously injured by these petty annoyances; but it is perfectly
true that the art and industry of man have not yet been able to
overcome the collective force, the individual perseverance, and the
complicated machinery of destruction which insects employ. A small ant,
according to a most careful and philosophical observer, opposes almost
invincible obstacles to the progress of civilization in many parts
of the equinoctial zone. These animals devour paper and parchment;
they destroy every book and manuscript. Many provinces of Spanish
America cannot, in consequence, show a written document of a hundred
years' existence. "What development," he adds, "can the civilization
of a people assume, if there be nothing to connect the present with
the past--if the depositories of human knowledge must be constantly
renewed--if the monuments of genius and wisdom cannot be transmitted
to posterity?"[F] Again, there are beetles which deposit their larvae
in trees in such formidable numbers that whole forests perish beyond
the power of remedy. The pines of the Hartz have thus been destroyed
to an enormous extent; and in North America, at one place in South
Carolina, at least ninety trees in every hundred, upon a tract of two
thousand acres, were swept away by a small black, winged bug. And
yet, according to Wilson, the historian of American birds, the people
of the United States were in the habit of destroying the redheaded
woodpecker, the great enemy of these insects, because he occasionally
spoilt an apple.[G] The same delightful writer and true naturalist,
speaking of the labours of the ivory-billed woodpecker, says, "Would
it be believed that the larvae of an insect or fly, no larger than
a grain of rice, should silently, and in one season, destroy some
thousand acres of pine-trees, many of them from two to three feet in
diameter, and a hundred and fifty feet high? In some places the whole
woods, as far as you can see around you, are dead, stripped of the
bark, their wintry-looking arms and bare trunks bleaching in the sun,
and tumbling in ruins before every blast."[H] The subterraneous larva
of some species of beetle has often caused a complete failure of the
seed-corn, as in the district of Halle in 1812.[I] The corn-weevil,
which extracts the flour from grain, leaving the husk behind, will
destroy the contents of the largest storehouses in a very short period.
The wire-worm and the turnip-fly are dreaded by every farmer. The
ravages of the locust are too well known not to be at once recollected
as an example of the formidable collective power of the insect race.
The white ants of tropical countries sweep away whole villages with
as much certainty as a fire or an inundation; and ships even have
been destroyed by these indefatigable republics. Our own docks and
embankments have been threatened by such minute ravagers.

The enormous injuries which insects cause to man may thus be held
as one reason for ceasing to consider the study of them as an
insignificant pursuit; for a knowledge of their structure, their food,
their enemies, and their general habits, may lead, as it often has
led, to the means of guarding against their injuries. At the same
time we derive from them both direct and indirect benefits. The honey
of the bee, the dye of the cochineal, and the web of the silk-worm,
the advantages of which are obvious, may well be balanced against
the destructive propensities of insects which are offensive to man.
But a philosophical study of natural history will teach us that the
direct benefits which insects confer upon us are even less important
than their general uses in maintaining the economy of the world. The
mischiefs which result to us from the rapid increase and the activity
of insects are merely results of the very principle by which they
confer upon us numberless indirect advantages. Forests are swept
away by minute beetles; but the same agencies relieve us from that
extreme abundance of vegetable matter which would render the earth
uninhabitable were this excess not periodically destroyed. In hot
countries the great business of removing corrupt animal matter, which
the vulture and hyaena imperfectly perform, is effected with certainty
and speed by the myriads of insects that spring from the eggs deposited
in every carcase by some fly seeking therein the means of life for
her progeny. Destruction and reproduction, the great laws of nature,
are carried on very greatly through the instrumentality of insects;
and the same principle regulates even the increase of particular
species of insects themselves. When aphides are so abundant that we
know not how to escape their ravages, flocks of lady-birds instantly
cover our fields and gardens to destroy them. Such considerations as
these are thrown out to show that the subject of insects has a great
philosophical importance--and what portion of the works of nature has
not? The habits of all God's creatures, whether they are noxious, or
harmless, or beneficial, are worthy objects of our study. If they
affect ourselves, in our health or our possessions, whether for good
or for evil, an additional impulse is naturally given to our desire
to attain a knowledge of their properties. Such studies form one of
the most interesting occupations which can engage a rational and
inquisitive mind; and, perhaps, none of the employments of human life
are more dignified than the investigation and survey of the workings
and the ways of nature in the minutest of her productions.

The exercise of that habit of observation which can alone make a
naturalist--"an out-of-door naturalist," as Daines Barrington calls
himself--is well calculated to strengthen even the most practical and
merely useful powers of the mind. One of the most valuable mental
acquirements is the power of discriminating among things which differ
in many minute points, but whose general similarity of appearance
usually deceives the common observer into a belief of their identity.
The study of insects, in this point of view, is most peculiarly adapted
for youth. According to our experience, it is exceedingly difficult for
persons arrived at manhood to acquire this power of discrimination;
but, in early life, a little care on the part of the parent or teacher
will render it comparatively easy. In this study the knowledge of
things should go along with that of words. "If names perish," says
Linnaeus, "the knowledge of things perishes also:"[J] and, without
names, how can any one communicate to another the knowledge he has
acquired relative to any particular fact, either of physiology, habit,
utility, or locality? On the other hand, mere catalogue learning is as
much to be rejected as the loose generalizations of the despisers of
classification and nomenclature. To name a plant, or an insect, or a
bird, or a quadruped rightly, is one step towards an accurate knowledge
of it; but it is not the knowledge itself. It is the means, and not the
end in natural history, as in every other science.

If the bias of opening curiosity be properly directed, there is not
any branch of natural history so fascinating to youth as the study of
insects. It is, indeed, a common practice in many families to teach
children, from their earliest infancy, to treat the greater number
of insects as if they were venomous and dangerous, and, of course,
meriting to be destroyed, or at least avoided with horror. Associations
are by this means linked with the very appearance of insects, which
become gradually more inveterate with advancing years; provided, as
most frequently happens, the same system be persisted in, of avoiding
or destroying almost every insect which is unlucky enough to attract
observation. How much rational amusement and innocent pleasure is
thus thoughtlessly lost; and how many disagreeable feelings are thus
created, in the most absurd manner! In order to show that the study
or (if the word be disliked) the observation of insects is peculiarly
fascinating to children, even in their early infancy, we may refer
to what we have seen in the family of a friend, who is partial to
this, as well as to all the departments of natural history. Our
friend's children, a boy and girl, were taught, from the moment they
could distinguish insects, to treat them as objects of interest and
curiosity, and not to be afraid even of those which wore the most
repulsive appearance. The little girl, for example, when just beginning
to walk alone, encountered one day a large staphylinus (_Goerius
olens?_ Stephens; vulgo, _the devil's coach-horse_), which she
fearlessly seized, and did not quit her hold, though the insect grasped
one of her fingers in his formidable jaws. The mother, who was by,
knew enough of the insect to be rather alarmed for the consequences,
though she prudently concealed her feelings from the child. She did
well; for the insect was not strong enough to break the skin, and
the child took no notice of its attempts to bite her finger. A whole
series of disagreeable associations with this formidable-looking family
of insects was thus averted at the very moment when a different mode
of acting on the part of the mother would have produced the contrary
effect. For more than two years after this occurrence the little girl
and her brother assisted in adding numerous specimens to their father's
collection, without the parents ever having cause, from any accident,
to repent of their employing themselves in this manner. The sequel
of the little girl's history strikingly illustrates the position for
which we contend. The child happened to be sent to a relative in the
country, where she was not long in having carefully instilled into her
mind all the usual antipathies against "everything that creepeth on
the earth;" and though she afterwards returned to her paternal home,
no persuasion or remonstrance could ever again persuade her to touch
a common beetle, much less a staphylinus, with its tail turned up in
a threatening attitude, and its formidable jaws ready extended for
attack or defence.[K] We do not wish that children should be encouraged
to expose themselves to danger in their encounters with insects. They
should be taught to avoid those few which are really noxious--to admire
all--to injure none.

The various beauty of insects--their glittering colours, their
graceful forms--supplies an inexhaustible source of attraction. Even
the most formidable insects, both in appearance and reality,--the
dragon-fly, which is perfectly harmless to man, and the wasp, whose
sting every human being almost instinctively shuns,--are splendid in
their appearance, and are painted with all the brilliancy of natural
hues. It has been remarked that the plumage of tropical birds is not
superior in vivid colouring to what may be observed in the greater
number of butterflies and moths.[L] "See," exclaims Linnaeus, "the
large, elegant painted wings of the butterfly, four in number, covered
with delicate feathery scales! With these it sustains itself in the
air a whole day, rivalling the flight of birds and the brilliancy
of the peacock. Consider this insect through the wonderful progress
of its life,--how different is the first period of its being from
the second, and both from the parent insect! Its changes are an
inexplicable enigma to us: we see a green caterpillar, furnished with
sixteen feet, feeding upon the leaves of a plant; this is changed into
a chrysalis, smooth, of golden lustre, hanging suspended to a fixed
point, without feet, and subsisting without food; this insect again
undergoes another transformation, acquires wings, and six feet, and
becomes a gay butterfly, sporting in the air, and living by suction
upon the honey of plants. What has nature produced more worthy of
our admiration than such an animal, coming upon the stage of the
world, and playing its part there under so many different masks?" The
ancients were so struck with the transformations of the butterfly,
and its revival from a seeming temporary death, as to have considered
it an emblem of the soul, the Greek word _pysche_ signifying both the
soul and a butterfly; and it is for this reason that we find the
butterfly introduced into their allegorical sculptures as an emblem
of immortality. Trifling, therefore, and perhaps contemptible, as to
the unthinking may seem the study of a butterfly, yet when we consider
the art and mechanism displayed in so minute a structure,--the fluids
circulating in vessels so small as almost to escape the sight--the
beauty of the wings and covering--and the manner in which each part
is adapted for its peculiar functions,--we cannot but be struck with
wonder and admiration, and allow, with Paley, that "the production of
beauty was as much in the Creator's mind in painting a butterfly as in
giving symmetry to the human form."

A collection of insects is to the true naturalist what a collection
of medals is to the accurate student of history. The mere collector,
who looks only to the shining wings of the one, or the green rust of
the other, derives little knowledge from his pursuit. But the cabinet
of the naturalist becomes rich in the most interesting subjects of
contemplation, when he regards it in the genuine spirit of scientific
inquiry. What, for instance, can be so delightful as to examine the
wonderful variety of structure in this portion of the creation; and,
above all, to trace the beautiful gradations by which one species runs
into another? Their differences are so minute, that an unpractised
eye would proclaim their identity; and yet, when the species are
separated, and not very distantly, they become visible even to
the common observer. It is in examinations such as these that the
naturalist finds a delight of the highest order. While it is thus one
of the legitimate objects of his study to attend to minute differences
of structure, form, and colouring, he is not less interested in the
investigation of habits and economy; and in this respect the insect
world is inexhaustibly rich. We find herein examples of instinct to
parallel those of all the larger animals, whether they are solitary
or social; and innumerable others besides, altogether unlike those
manifested in the superior departments of animated nature. These
instincts have various directions, and are developed in a more or less
striking manner to our senses, according to the force of the motive by
which they are governed. Some of their instincts have for their object
the preservation of insects from external attack; some have reference
to procuring food, and involve many remarkable stratagems; some direct
their social economy, and regulate the condition under which they
live together either in monarchies or republics, their colonizations,
and their migrations; but the most powerful instinct which belongs
to insects has regard to the preservation of their species. We find,
accordingly, that as the necessity for this preservation is of the
utmost importance in the economy of nature, so for this especial object
many insects, whose offspring, whether in the egg or the larva state,
are peculiarly exposed to danger, are endued with an almost miraculous
foresight, and with an ingenuity, perseverance, and unconquerable
industry, for the purpose of avoiding those dangers, which are not to
be paralleled even by the most singular efforts of human contrivance.
The same ingenuity which is employed for protecting either eggs, or
caterpillars and grubs, or pupae and chrysalides, is also exercised
by many insects for their own preservation against the changes of
temperature to which they are exposed, or against their natural
enemies. Many species employ those contrivances during the period of
their hibernation, or winter sleep. For all these purposes some dig
holes in the earth, and form them into cells; others build nests of
extraneous substances, such as bits of wood and leaves; others roll
up leaves into cases, which they close with the most curious art;
others build a house of mud, and line it with the cotton of trees, or
the petals of the most delicate flowers; others construct cells, of
secretions from their own bodies; others form cocoons, in which they
undergo their transformation; and others dig subterraneous galleries,
which, in their complexity of arrangement, in solidity, and in complete
adaptation to their purposes, vie with the cities of civilised man. The
contrivances by which insects effect these objects have been accurately
observed and minutely described, by patient and philosophical
inquirers, who knew that such employments of the instinct with which
each species is endowed by its Creator offered the most valuable and
instructive lessons, and opened to them a wide field of the most
delightful study. The construction of their habitations is certainly
among the most remarkable peculiarities in the economy of insects; and
it is of this subject that we propose to treat under the general name,
which is sufficiently applicable to our purpose, of Insect Architecture.

In the descriptions which we shall give of Insect Architecture, we
shall employ as few technical words as possible: and such as we cannot
well avoid, we shall explain in their places; but, since our subject
chiefly relates to the reproduction of insects, it may be useful to
many readers to introduce here a brief description of the changes which
they undergo.

[Illustration: Magnified eggs, of _a_, _Geometra armillata_; _b_, of an
unknown water insect; _c_, of the lacquey moth; _d_, of a caddis-fly
(_Phryganea atrata_); _e_, of red under-wing moth (_Catocala nupta_);
_f_, of _Pontia Brassicae_; _g_, of the Clifden Nonpareil moth.]

It was of old believed that insects were produced spontaneously by
putrefying substances; and Virgil gives the details of a process for
_creating_ a swarm of bees out of the carcase of a bull; but Redi, a
celebrated Italian naturalist, proved by rigid experiments that they
are always, in such cases, hatched from _eggs_ previously laid. Most
insects, indeed, lay eggs, though some few are viviparous, and some
propagate both ways. The eggs of insects are very various in form,
and seldom shaped like those of birds. We have here figured those of
several species, as they appear under the microscope.

When an insect first issues from the egg, it is called by naturalists
_larva_, and, popularly, a caterpillar, a grub, or a maggot. The
distinction, in popular language, seems to be, that _caterpillars_ are
produced from the eggs of moths or butterflies; _grubs_ from the eggs
of beetles, bees, wasps, &c.; and _maggots_ (which are without feet)
from blow-flies, house-flies, cheese-flies, &c., though this is not
very rigidly adhered to in common parlance. Maggots are also sometimes
called _worms_, as in the instance of the meal-worm; but the common
earth-worm is not a larva, nor is it by modern naturalists ranked among
insects.

[Illustration: _a_, Ametabolous pupa of Cicada; _b_, caterpillar of
tussock moth (_Laria fascelina_); _c_, larva of the poplar beetle
(_Chrysomela populi_); _d_, larva of Sinex; _e_, larva of the common
gnat.]

There are, however, certain larvae, as those of the Cicada, the
crickets, the water-boatman (_Notonecta_), the cockroach, &c., which
resemble the perfect insects in form, excepting that they are destitute
of wings; but in the pupa state these appear in a rudimentary
condition, at least in such species as have wings in the mature stage
of existence. The pupae are active and eat. Insects, the larvae and pupae
of which are so similar to the adults, are termed _Ametabolous_ (_a_,
without, [Greek: metabole], change); those the larvae of which undergo
changes of a marked character, _Metabolous_ (_Insecta ametabola_ and
_Insecta metabola_, Burmeister).

Larvae are remarkably small at first, but grow rapidly. The full-grown
caterpillar of the goat-moth (_Cossus ligniperda_) is thus seventy-two
thousand times heavier than when it issues from the egg; and the
maggot of the blow-fly is, in twenty-four hours, one hundred and
fifty-five times heavier than at its birth. Some larvae have feet,
others are without; none have wings. They cannot propagate. They feed
voraciously on coarse substances; and as they increase in size, which
they do very rapidly, they cast their skins three or four times. In
defending themselves from injury, and in preparing for their change by
the construction of secure abodes, they manifest great ingenuity and
mechanical skill. The figures on the preceding page exemplify various
forms of insects in this stage of their existence.

[Illustration: _a_, Pupa of a Water-Beetle (_Hydrophilus_); _b_, pupa
of _Sphinx Ligustri_.]

When larvae are full grown, they cast their skins for the last time,
undergo a complete change of form, excepting in the case of ametabolous
larvae, cease to eat, and remain nearly motionless. The inner skin
of the larva now becomes converted into a membranous or leathery
covering, which wraps the insect closely up like a mummy: in this
condition it is termed _Pupa_, from its resemblance to an infant in
swaddling bands. Nympha, or nymph, is another term given to insects
in this stage;[M] moreover from the pupae of many of the butterflies
appearing gilt as if with gold, the Greeks called them _Chrysalides_,
and the Romans _Aureliae_, and hence naturalists frequently call a pupa
_chrysalis_, even when it is not gilt. We shall see, as we proceed,
the curious contrivances resorted to for protecting insects in this
helpless state. The following are examples of insects in the _imago_,
or perfect state.

[Illustration: Insects in the Imago or perfect state.

_a_, _Nemopteryx coa_, Leach.--_b_, _Myrmeleon formicalynx_,
Fabricius.--_c_, _Hesperia comma_, Fabricius.--_d_, _Nepa cinerea_,
Linnaeus.]

After a certain time, the insect which has remained in its pupa-case,
like a mass of jelly without shape, is gradually preparing for its
final change, when it takes the form of a perfect insect. This state
was called by Linnaeus _Imago_, because the insect, having thrown off
its mask, becomes a perfect _image_ of its species. Of some, this
last portion of their existence is very short, others live through
a year, and some exist for longer periods. They feed lightly, and
never increase in size. The chief object of all is to perpetuate
their species, after which the greater number quickly die. It is in
this state that they exercise those remarkable instincts for the
preservation of their race, which are exhibited in their preparations
for the shelter of their eggs, and the nourishment of their larvae.




_CHAPTER II._

STRUCTURES FOR PROTECTING EGGS.--MASON-WASPS; MASON-BEES; MINING-BEES.


The provisions which are made by the different species of insects
for protecting their eggs, appear in many cases to be admirably
proportioned to the kind of danger and destruction to which they
may be exposed. The eggs themselves, indeed, are not so liable to
depredation and injury as the young brood hatched from them; for, like
the seeds of plants, they are capable of withstanding greater degrees
both of heat and cold than the insects which produce them. According
to the experiments of Spallanzani, the eggs of frogs that had been
exposed to various degrees of artificial heat were scarcely altered in
their productive powers by a temperature of 111 deg. of Fahrenheit, but
they became corrupted after 133 deg. He tried the same experiment upon
tadpoles and frogs, and found they all died at 111 deg. Silkworms died at
a temperature of 108 deg., while their eggs did not entirely cease to be
fertile till 144 deg. The larvae of flesh-flies perished, while the eggs
of the same species continued fertile, at about the same comparative
degrees of heat as in the preceding instances. Intense cold has a
still less effect upon eggs than extreme heat. Spallanzani exposed the
eggs of silk-worms to an artificial cold 23 deg. below zero, and yet, in
the subsequent spring, they all produced caterpillars. Insects almost
invariably die at the temperature of 14 deg., that is, at 18 deg. below the
freezing point.[N] The care of insects for the protection of their eggs
is not entirely directed to their preservation in the most favourable
temperature for being hatched, but to secure them against the numerous
enemies which would attempt their destruction; and, above all, to
protect the grubs, when they are first developed, from those injuries
to which they are peculiarly exposed. Their prospective contrivances
for accomplishing these objects are in the highest degree curious.

Most persons have more or less acquaintance with the hives of the
social species of bees and wasps; but little is generally known of the
nests constructed by the solitary species, though in many respects
these are not inferior to the others in displays of ingenuity and
skill. We admire the social bees, labouring together for one common
end, in the same way that we look with delight upon the great division
of labour in a well-ordered manufactory. As in a cotton-mill some
attend to the carding of the raw material, some to its formation into
single threads, some to the gathering these threads upon spindles,
others to the union of many threads into one,--all labouring with
invariable precision because they attend to a single object;--so do
we view with delight and wonder the successive steps by which the
hive-bees bring their beautiful work to its completion,--striving, by
individual efforts, to accomplish their general task, never impeding
each other by useless assistance, each taking a particular department,
and each knowing its own duties. We may, however, not the less admire
the solitary wasp or bee, who begins and finishes every part of its
destined work; just as we admire the ingenious mechanic who perfects
something useful or ornamental entirely by the labour of his own
hands,--whether he be the patient Chinese carver, who cuts the most
elaborately-decorated boxes out of a solid piece of ivory, or the
turner of Europe, who produces every variety of elegant form by the
skilful application of the simplest means.

Our island abounds with many varieties of solitary wasps and bees; and
their nests may therefore be easily discovered by those who, in the
proper seasons, are desirous of observing the peculiarities of their
architecture.

[Illustration: _Odynerus._--Natural size.]


Mason-Wasps.

In September, 1828, a common species of solitary mason-wasp
(_Odynerus_, Latr.) was observed by us (J. R.) on the east wall of
a house at Lee, in Kent, very busy in excavating a hole in one of
the bricks, about five feet from the ground. Whether there might not
have been an accidental hole in the brick before the wasp commenced
her labours, is unknown, as she had made considerable progress in
the work when first observed: but the brick was one of the hardest
of the yellow sort made in this neighbourhood. The most remarkable
circumstance in the process of hewing into the brick was the care of
the insect in removing to a distance the fragments which from time
to time she succeeded in detaching. It did not appear to suit her
design to wear down the brick, particle by particle, as the furniture
beetle (_Anobium pertinax_) does in making its pin-hole galleries in
old wood. Our wasp-architect, on the contrary, by means of her strong
_tranchant_-toothed jaws, severed a piece usually about the bigness
of a mustard-seed. It might have been supposed that these fragments
would have been tossed out of the hole as the work proceeded, without
further concern; as the mole tosses above ground the earth which
has been cleared out of its subterranean gallery. The wasp was of a
different opinion; for it was possible that a heap of brick chips,
at the bottom of the wall, might lead to the discovery of her nest
by some of her enemies, particularly by one or other of the numerous
tribe of what are called _ichneumon_-flies. This name is given to
them, from the similarity of their habit of destroying eggs, to that
of the little animal which proves so formidable an enemy to the
multiplication of the crocodile of Egypt. They may be also denominated
_cuckoo_-flies, because, like that bird, they thrust their egg into
the nest of another species. These flies are continually prowling
about and prying into every corner, to find, by stealth, a nidus for
their eggs. It might have been some such consideration as this which
induced the wasp to carry off the fragments as they were successively
detached. That concealment was the motive, indeed, was proved: for
one of the fragments which fell out of the hole by accident, she
immediately sought for at the bottom of the wall, and carried off
like the rest. It was no easy matter to get out one of the fragments,
as may readily be conceived when the size of the insect is compared
with that of the entrance of which this ([Illustration]) is the exact
size, as taken from the impression of a bit of dough upon the hole
when finished. It was only by seizing the fragment with her jaws, and
retreating backwards, that the matter could be accomplished; though,
after the interior of the excavation was barely large enough to admit
of her turning round, she more than once attempted to make her exit
head-foremost, but always unsuccessfully. The weight of the fragments
removed did not appear to impede her flight, and she generally returned
to her task in about two or three minutes.

[Illustration: Mandibles--Jaws of Mason-Wasp.--Greatly magnified.]

Within two days the excavation was completed; but it required two other
days to line it with a coating of clay, to deposit the eggs, two in
number, and, no doubt, to imprison a few live spiders or caterpillars
for the young when hatched--a process which was first observed by Ray
and Willughby,[O] but which has since been frequently ascertained. In
the present instance, this peculiarity was not seen; but the little
architect was detected in closing up the entrance, which was formed of
a layer of clay more than double the thickness of the interior lining.
In November following, we hewed away the brick around this nest, and
found the whole excavation was rather less than an inch in depth.

[Illustration: Cuckoo-Fly (_Tachina larvarum?_).--Natural size.]

Notwithstanding all the precautions of the careful parent to conceal
her nest it was found out by one of the cuckoo-flies (_Tachina
larvarum?_)--probably a common species very similar to the house-fly,
but rather larger, which deposited an egg there; and the grub hatched
from it, after devouring one of the wasp-grubs, formed itself a cocoon
(_a_), as did the other undevoured grub of the wasp (_b_). Both awaited
the return of summer to change into winged insects, burst their
cerements, and proceed as their parents did.

[Illustration: Mason-Wasp's Nest and Cocoons.--About one-third the
natural size.]

[Illustration: Mason-Wasp (_Odynerus murarius_).--Natural size.]

Another mason-wasp (_Odynerus murarius_, Latr.), differing little in
appearance from the former, may often be seen frequenting sandy banks
exposed to the sun, and constructing its singular burrows. The sort
of sand-bank which it selects is hard and compact; and though this
may be more difficult to penetrate, the walls are not liable to fall
down upon the little miner. In such a bank, the mason-wasp bores a
tubular gallery two or three inches deep. The sand upon which Reaumur
found some of these wasps at work was almost as hard as stone, and
yielded with difficulty to his nail; but the wasps dug into it with
ease, having recourse, as he ascertained, to the ingenious device of
moistening it by letting fall two or three drops of fluid from their
mouth, which rendered the mass ductile, and the separation of the
grains easy to the double pickaxe of the little pioneers.

[Illustration: Nests, &c., of Mason-Wasps.--About half the natural size.

_a_, The tower of the nest; _b_, the entrance after the tower is
removed; _c_, the cell; _d_, the cell, with a roll of caterpillars
prepared for the larva.]

When this wasp has detached a few grains of the moistened sand, it
kneads them together into a pellet about the size of one of the seeds
of a gooseberry. With the first pellet which it detaches, it lays
the foundation of a round tower, as an outwork, immediately over the
mouth of its nest. Every pellet which it afterwards carries off from
the interior is added to the wall of this outer round tower, which
advances in height as the hole in the sand increases in depth. Every
two or three minutes, however, during these operations, it takes a
short excursion, for the purpose, probably, of replenishing its store
of fluid wherewith to moisten the sand. Yet so little time is lost,
that Reaumur has seen a mason-wasp dig in an hour a hole the length of
its body, and at the same time build as much of its round tower. For
the greater part of its height this round tower is perpendicular; but
towards the summit it bends into a curve, corresponding to the bend
of the insect's body, which in all cases of insect architecture, is
the model followed. The pellets which form the walls of the tower are
not very nicely joined, and numerous vacuities are left between them,
giving it the appearance of filigree-work. That it should be thus
slightly built is not surprising, for it is intended as a temporary
structure for protecting the insect while it is excavating its hole,
and as a pile of materials, well arranged and ready at hand, for the
completion of the interior building,--in the same way that workmen make
a regular pile of bricks near the spot where they are going to build.
This seems, in fact, to be the main design of the tower, which is taken
down as expeditiously as it had been reared. Reaumur thinks that, by
piling in the sand which has previously been dug out, the wasp intends
to guard her progeny for a time from being exposed to the too violent
heat of the sun; and he has even sometimes seen that there were not
sufficient materials in the tower, in which case the wasp had recourse
to the rubbish she had thrown out after the tower was completed. By
raising a tower of the materials which she excavates, the wasp produces
the same shelter from external heat as a human creature would who chose
to inhabit a deep cellar of a high house. She further protects her
progeny from the ichneumon-fly, as the engineer constructs an outwork
to render more difficult the approach of an enemy to the citadel.
Reaumur has seen this indefatigable enemy of the wasp peep into the
mouth of the tower, and then retreat, apparently frightened at the
depth of the cell which he was anxious to invade.

The mason-wasp does not furnish the cell she has thus constructed with
pollen and honey, like the solitary bees, but with living caterpillars,
and these always of the same species--being of a green colour, and
without feet. She fixes the caterpillars together in a spiral column:
they cannot alter their position, although they remain alive. They
are an easy prey to their smaller enemy; and when the grub has eaten
them all up, it spins a case, and is transformed into a pupa, which
afterwards becomes a wasp. The number of caterpillars which is thus
found in the lower cavity of the mason-wasp's nest is ordinarily from
ten to twelve. The mother is careful to lay in the exact quantity of
provision which is necessary to the growth of the grub before he quits
his retreat. He works through his store till his increase in this
state is perfected, and he is on the point of undergoing a change into
another state, in which he requires no food. The careful purveyor,
cruel indeed in her choice of a supply, but not the less directed by
an unerring instinct, selects such caterpillars as she is conscious
have completed their growth, and will remain thus imprisoned without
increase or corruption till their destroyer has gradually satisfied
the necessities of his being. "All that the worm of the wasp," says
Reaumur, "has to do in his nest, from his birth to his transformation,
is to eat." There is another species of wasp which does not at once
enclose in its nest all the sustenance which its larva will require
before transformation, but which from time to time imprisons a living
caterpillar, and when that is consumed, opens the nest and introduces
another.

[The upper figure in the accompanying illustration exhibits two of the
curious towers built by this interesting insect and drawn of their
natural size.]

The insect is one of the most plentiful in England, and can be found
on sunny days, flitting about sand-banks and making its curious
habitations. The length is nearly half an inch, and the colour is
black, variegated with five yellow bands upon the abdomen.

The lower figure represents the habitations of one of the British
solitary wasps, _Pompilus punctum_, and is given in order to show a
curious resemblance in the structure. The specimen from which the
sketch was taken was found under the eaves of a roof which protected
a bee-hive. The cells were thirteen in number, very carefully
constructed of earth, and several of them were closed. Although these
cells were not fossorial in their nature, several other species of
the same genus are as accomplished burrowers as any insect. _Pompilus
plumbeus_, for example, another black species, burrows into sand, and
is very plentiful on our more southern shores. It may usually be found
hovering about sand-banks, and flitting about with such agility that it
is by no means an easy insect to catch. The male is peculiarly apt to
evade the stroke of the entomologist's net.

[Illustration]

[Illustration]

Then there is _Pompilus rufipes_, which is a black insect, but
distinguished by the conspicuous red colour of the hind legs. This is
very fond of our coasts, and may be found wherever the soil is suitable
for its excavations. Many species of this genus carry off spiders for
the purpose of provisioning their nests. Several species, which live
far inland, prefer light and dry earth to sand, and make therein their
burrows, preferring our little white spider as the provision for their
young. Although the same insect may be often observed to carry the
same kind of prey to its home, it does not at all follow that no change
is ever made.

But the most remarkable example of this fact may be found in a very
common swift-winged insect, black in colour, with a reddish patch on
the end of the abdomen. Its name is _Trachytes pompiliformis_, and
it generally stocks its nest with small caterpillars. Mr. F. Smith,
however, has taken it when in the act of carrying off a small species
of grasshopper--certainly the very last insect that would be thought of
as likely to be immured by a captor which must be scarcely larger than
itself.

This insect is to be found in most warm and sandy situations, and may
be looked for at the end of summer and beginning of autumn. It may be
easily known by its red spot on the abdomen, and the large, transverse
head; it is wider than the thorax.

One species of mining-bee, not often found in England, chooses some
very singular insects wherewith to feed its young. Its name is
_Philanthus triangulum_, and it is a very fierce, waspish-looking
creature, with a large wide head, wider even than the thorax, sharp and
powerful jaws, and with broad wings. The head and thighs are black,
with a few spots of a yellowish white, and the abdomen is yellow, with
a black spot in the middle of each segment. Its length rather exceeds
half an inch. The actions of this insect do not belie its looks, for it
is a fierce and active creature, seizing upon various bees and dragging
them into its tunnel.

Mr. F. Smith discovered the metropolis of this usually scarce insect
at Sandown Bay, in the Isle of Wight, and has given an interesting
description of its habits. He states that although it is so ferocious
towards other insects, it appears to be perfectly harmless as far as
man is concerned, allowing itself to be handled without even attempting
to use its sting. Indeed, he was quite unable to provoke the insect to
do so. Various bees were captured by the Philanthus, and the favourites
seemed to belong to the genus Andrena, itself a burrowing bee, and the
common hive-bee. The Philanthus seemed perfectly indifferent whether
they attacked the comparatively small and feeble Andrena, or the
formidable hive-bee, taking them as they came, and caring nothing
for the sting. The Philanthus that burrowed on the top of the cliff,
seemed to prefer the hive-bee, because the red clover attracted greater
numbers of that insect. Those that made their burrows at the top of the
cliff, took the Andrenae. Of course, the Philanthus is obliged to catch
more of the Andrenae than the hive bees. Only one species of this genus
is known in England; it is to be found in July and August.

There is a very large genus of rather small humming-bees, many of which
are popularly mistaken for wasps, on account of their sharply pointed
and yellow banded abdomen; they belong to the genus Crabro, and are
extremely variable in the material into which they burrow, and the
insects with which they feed their young. Some species burrow into dry
bramble sticks. If the reader should wish to obtain specimens of them,
as well as other burrowers, he will find bramble, rose, and jessamine
sticks most prolific in them. The best plan is to collect a quantity
of these sticks and put them into glass tubes, with the ends stopped
with wire gauze; there is then an absolute certainty of identifying the
insect with its habitation. The spring is the best time for collecting.
Sometimes these creatures are afflicted with parasites, which also are
detained in the tube, so as to yield valuable information to the captor.

Some species burrow in sand-banks and feed their young with gnats,
others burrow into dead timber, and stock their tunnels with flies
of various kinds. One very useful species, _Crabro laevis_, burrows
in sand-banks, and provisions its nest with the noxious turnip-fleas
(_Halticae_), great numbers of which are needed to stock a single
burrow. It is rather a social insect, many burrows being often found
near each other. The turnip-flea has so hard a shell, that the young
Crabro seems hardly capable of eating it. Mr. Smith, however, has
remarked that another burrowing-bee stocks its nest with certain
weevils that are almost too hard to be pierced with a pin, and that the
shell is probably softened by the damp ground. The greater number of
this group, however, are burrowers into the ground, and stock their
nests with flies of some kind.

Another species of this large genus, _Crabro luteipalpis_, is fond of
making its burrows in the mortar of old walls, preferring those spots
where nails have been drawn, making the process of burrowing easier
for the insect. It is not uncommon in the outskirts of London. All
gardeners, especially those who cultivate roses, ought to encourage
this very little insect, and welcome its presence, for it provisions
its nest with the aphides, or green blight, which infect the
rose-trees, and which have destroyed so many promising plants.

The female, which is the larger of the two sexes, measures only three
lines in length. The colour is shining black, and the head is rather
squared.

Among other burrowing species of this genus we may mention _Crabro
varius_, a rather long and slender insect, black in colour, with yellow
spottings about the thorax. It prefers very hard fine sand, such as is
found in partially excavated sand-banks, and provisions its burrows
with gnats. It is tolerably plentiful.

Our last example of the earth-burrowers belonging to this genus is
_Crabro Wesmoeli_, which chooses similar localities, being mostly found
in sand-banks. It carries off flies of different kinds for the food
of its young. There is a very common insect, closely allied to the
last mentioned genus, whose horns are worthy of notice. This is called
_Typoxylon figulus_. It is a small creature, with a large head and
slender abdomen. Its colour is black, and on the edges of the segments
of the abdomen there is a little silvery shining down.

It generally burrows into light earth, though it sometimes drives its
tunnel into decayed wood. In either case, it provisions its nest with
spiders, flying into the hedges, pulling the unfortunate spiders out
of their webs, and carrying them into the burrow. One burrow contains
a series of cells, which are separated from each other by partitions
of sand, the particles of which are firmly cemented together by some
glutinous substance secreted by the insect. Some species of this genus
burrow into the pith of the bramble and other shrubs.

One of the most determined of our British burrowers is the insect which
is known by the name of _Ammophila sabulosa_. It has a large, squared
head, wider than the thorax, a very long and slender body, and short
though powerful wings. The colour is black, with a slight rust-red tint
on the base of the abdomen.

When the female has dug her burrow, she sets off in search of a
caterpillar of proportionate size, and having conveyed it into her
dwelling, she affixes an egg to the imprisoned larva, and goes off in
search of another, carefully stopping up the entrance with stones. In
fine weather she will fill one burrow with caterpillars in a few hours,
and then begin another nursery for the future young. This species
appears always to make use of caterpillars, but another allied species
prefers spiders. Mr. F. Smith mentions that he has found in a high
sand-bank as many as twenty females apparently hibernating together
till suitable weather enabled them to pursue their usual economy.

There really seems to be scarcely any genus of insect that is not
seized upon by one or other of these burrowers, and packed away in a
half living state to form food for their young. There is one of these
solitary burrowing wasps called the _Astata boops_, deriving its
specific name from its large round eyes, which in the male completely
unite at the back of the head. The abdomen is shaped something like
a boy's peg-top, or a symmetrical turnip, the peg of the top, or the
point of the turnip, corresponding to the top of the abdomen. Its
length is about half an inch, and its colour is black, with a rust-red
patch on the end of the abdomen.

There is a remarkably pretty, and very variable, sand-wasp, which is
plentiful in most parts of the country. The colour is black, and the
abdomen is banded by four yellow bars. Its feet are also yellow. Mr.
Smith has written a very interesting account of the proceedings of this
insect.

"Having frequently observed the habits of the type of this genus,
_Mellinus arvensis_, and reared it from the larva state, a few
observations are here recorded. When the parent insect has formed
a burrow of the required length, and enlarged the extremity into
a chamber of proper dimensions, she issues forth in search of the
proper nutriment for her young; this consists of various dipterous
insects: species of various genera are equally adapted to her
purpose--_Muscidae_, _Syrphidae_, &c., are captured.

"It is amusing to see four or five females lie in wait upon a patch
of cow-dung until some luckless fly settles on it. When this happens,
a cunning and gradual approach is made; a sudden attempt would not
succeed. The fly is the insect of quickest flight, therefore a degree
of intrigue is necessary. This is managed by running past the victim
slowly, and apparently in an unconcerned manner, until the poor fly is
caught unawares, and carried off by the Mellinus to its burrow. The
first fly being deposited, an egg is laid. The necessary number of
flies are soon secured, and her task is completed. Sometimes she is
interrupted by rainy weather, and it is some days ere she can store up
the quantity required.

"A larva found feeding became full-fed in ten days. Six flies were
devoured, the heads, harder parts of the throat, portions of the
abdomen, and the legs, being left untouched. The larva spins a tough,
thin, brown silken cocoon, passes the winter and spring in the larva
state, changes to the nymph on the approach of summer, and appears
about the beginning of autumn in the perfect state."

There is a genus of hymenopterous insects known by the name of
_Scolia_, which are remarkable for their fossorial powers. The species
represented in the engraving is called _Scolia Xantiana_, and is a
native of California.

When the female Scolia is about to fulfil the great object for which
she came into the world, she looks about for a suitable spot, where
the ground is not too hard, and digs a perpendicular burrow of some
depth, enlarging it at the bottom, and digging horizontally, so that
the general shape of the burrow somewhat resembles that of a boot. When
the burrow is completed, the insect flies off in search of food for
its young, and presently returns, bearing with her a grub, which she
clasps tightly under her chest, so that her wings may be at liberty.
She then takes the grub to the bottom of the tunnel, deposits an egg
upon it, and if the grub be a small one, goes off to fetch another.
When a sufficiency of food has been obtained, she covers up the grub
and egg and leaves the latter to its fate. In due time it is hatched,
and begins straightway to feed upon its unfortunate fellow-prisoner.
When all the food is gone, it is old enough to assume the perfect form,
and when it finally becomes a perfect insect, it makes its way into the
open air, and straightway looks out for a mate.

[Illustration]

An European species of this genus, which is called _Scolia flavifrons_,
is remarkable for the four large, round spots on the upper surface
of the abdomen. This species always feeds its young on the grub of a
beetle, one of the lamellicorn group, and in this case the grub is so
large that one is sufficient.

In the illustration, the left hand figure shows a section of the burrow
of _Scolia Xantiana_, and exhibits the enlarged portion of the tunnel
in which are placed the young Scolia and the unfortunate grub which has
to serve it for food. The insect itself is seen in the centre.

For figures 3 and 4 the reader is referred to the heading "Spiders."

There is another British insect which feeds its young with flies, and
which catches them in a manner somewhat similar to that which has
recently been narrated when treating of the Mellinus. The insect in
question is called _Oxybelus unuglumis_, and is a very pretty species.
Its length is seldom much more than a quarter of an inch, and its
colour is black, with some silvery hair about the face, and with some
spots and bands of white, more or less yellowish, upon the pointed
abdomen. The male is usually smaller than the female, but compensates
for this want of size by his more brilliant colouring.

Mr. F. Smith has described to me the method employed by this insect in
catching flies. In the air it would not have a chance of success, and
so it proceeds after a fashion very much like that which is adopted
by the hunting-spider. Choosing some spot where flies are likely to
settle, such as a bare, sunny bank, the Oxybelus alights upon it and
begins to run about without any apparent motive. At first the flies
are rather alarmed, but after a while they become accustomed to the
rapid movements of their foe, and allow it to come nearer and nearer
the cause of its perambulations. As soon as it has succeeded in drawing
within a few inches of a fly, the Oxybelus leaps upon it, just like the
hunting spider on its prey, and flies off before the victim knows that
an attack is even meditated.

The burrow of this species is made in hard white sand.

Several species of the genus _Cerceris_ are noted, not only as
burrowers, but for the exceeding variety of the food which they store
in their dwellings. The most common species, _Cerceris arenaria_, makes
its tunnel in hard, sandy spots, and is usually to be found about the
middle of July and August. The length of this insect rather exceeds
half an inch, and its colour is black, profusely spotted and barred
with yellow. It is rather slenderly made, and gives little external
indications of the great strength which it possesses.

This insect prefers to stock its nest with weevils of different
kinds--a most singular choice, when the hardness of the exterior
is taken into consideration. The well-known nut-weevil (_Balaninus
nucum_), with its hard, round body, and long mouth, is frequently taken
by this species of Cerceris, and Mr. Smith further mentions that he
has captured it in the act of taking the weevil called _Otiorhynchus
sulcatus_ to its nest.

This beetle is among the most noxious of our garden foes, and the more
so because its ravages are unseen. In its larval state it infests the
roots of many of our succulent plants and flowers, and has a habit of
eating away the plant just at the junction of the root and stem. Even
flowers in pots are apt to be infested by this insect, and often die
without the cause of their death being discovered. It is about half an
inch in length, white, and is destitute of feet, their office being
performed by bundles of stiff hairs, which are dispersed round the body.

In its perfect state it is about the third of an inch in length, the
colour is black, covered with a coating of very fine and short grey
hairs, and along its back are a number of short longitudinal grooves.
From this latter circumstance it derives its name of "_sulcatus_," or
grooved.

The exterior of this beetle is extremely hard, even exceptionally so
among the hard-bodied weevils. It is extremely difficult to get a pin
through the body, and the entomologist is often obliged to bore a hole
with a stout needle before the pin can be inserted. Yet, the Cerceris
uses this insect as the food of its young, and stores them away in
its burrow. That the young should eat them seems as impossible as if
a lobster or a box-tortoise had been inserted in their place. It is,
however, thought by most practical entomologists that the shell of the
weevil is softened by lying in the damp ground, and that as the young
is not hatched for several days after the burrow is sealed up, the
hard wing cases have time to soften.

Another species of the same genus, _Cerceris interrupta_, has the
curious habit of making its burrow in the hardest ground which it can
penetrate, and is generally to be found in well used footpaths. This
species also uses weevils for the food of its young, but prefers those
small weevils which are classed under the genus _Apion_, and which are
readily known by their pear-shaped bodies and rather elongated heads.
[There are about seventy species of _Apion_, so that the Cerceris has
plenty of choice.]


Mason-Bees.

It would not be easy to find a more simple, and, at the same time,
ingenious specimen of insect architecture than the nests of those
species of solitary bees which have been justly called mason-bees
(_Megachile_, Latreille). Reaumur, who was struck by the analogies
between the proceedings of insects and human arts, first gave to bees,
wasps, and caterpillars those names which indicate the character of
their labours; and which, though they may be considered a little
fanciful, are at least calculated to arrest the attention. The nests
of mason-bees are constructed of various materials; some with sand,
some with earth mixed with chalk, and some with a mixture of earthy
substances and wood.

[Illustration: Mason-Bee (_Anthophora retusa_).--Natural size.]

On the north-east wall of Greenwich Park, facing the road, and about
four feet from the ground, we discovered (J. R.), December 10th, 1828,
the nest of a mason-bee, formed in the perpendicular line of cement
between two bricks. Externally there was an irregular cake of dry mud,
precisely as if a handful of wet road-stuff had been taken from a
cart-rut and thrown against the wall; though, upon closer inspection,
the cake contained more small stones than usually occur in the mud of
the adjacent cart-ruts. We should in fact have passed it by without
notice had there not been a circular hole on one side of it, indicating
the perforation of some insect. This hole was found to be the orifice
of a cell about an inch deep, exactly of the form and size of a lady's
thimble, finely polished, and of the colour of plaster-of-paris, but
stained in various places with yellow.

[Illustration: Exterior Wall of Mason-Bee's Nest.]

This cell was empty; but, upon removing the cake of mud, we discovered
another cell, separated from the former by a partition about a quarter
of an inch thick, and in it a living bee, from which the preceding
figure was drawn, and which, as we supposed, had just changed from the
pupa to the winged state, in consequence of the uncommon mildness of
the weather. The one which had occupied the adjacent cell had no doubt
already dug its way out of its prison, and would probably fall a victim
to the first frost.

[Illustration: Cells of a Mason-Bee (_Anthophora retusa_).--One-third
the natural size.]

Our nest contained only two cells--perhaps from there not being room
between the bricks for more.

[There are only four British species of this genus. One species, _A.
acervorum_, seems perfectly indifferent whether it burrows into banks
or into the mortar of old walls. If possible, the former locality seems
to be the most favoured.

This species is notable for the many parasites who infect the
habitation and destroy the inmates. Perhaps the very worst and most
destructive of these parasites is the common earwig, which wreaks
wholesale desolation in the nest. It creeps into the burrow, and if it
finds a store of pollen laid up for the young, it will eat the pollen.
But if the young grub be hatched it will eat the grub. If the inmate
be in the pupal state, or even if it be ready to emerge in its perfect
condition, the earwig will eat it.

There are two bees which are parasitic upon this unfortunate insect,
both belonging the genus _Melecta_.

But the most destructive of these parasites appears to be an insect
which belongs to the great family of _Chalcididae_. These insects are
of the hymenopterous order, are of very minute dimensions, and of the
most brilliant colours. Indeed, if they were an inch or two in length,
instead of the eighth or twelfth of an inch, they would not suffer in
comparison with the most gorgeous inhabitants of tropical countries.

Their forms are most eccentric, some species having the abdomen small
and round and set on a long footstalk, while others have that portion
of the body placed so closely against the thorax, that the short
footstalk is scarcely visible. Others have certain joints of the legs
so large that a single joint equals the entire abdomen. Some have
the ovipositor projecting boldly from the body, while others have it
tucked up underneath, and others again have it quite short. But there
is one point which distinguishes them all, namely, the almost veinless
character of the wings.

Some of the _Chalcididae_ are parasitic upon insects in their earliest
stages, actually depositing their eggs in those of moths and
butterflies. Others are entirely parasitic upon parasites, laying
their eggs in the aphidii, which are parasites of the aphis. Some
of them haunt the galls, and contrive to make their young parasitic
upon the immature cynipidae which lie within the gall. The common
small tortoise-shell butterfly is terribly infested with these little
creatures, and we have bred hundreds of the gem-like _Chalcididae_ from
the larvae and pupae of that butterfly.

One of the _Chalcididae_, belonging to the genus _Melittobia_, is a
parasite upon the _Anthophora_; and the curious part of the proceeding
is, that it finds there another parasite, which becomes developed in
the home of the bee: the _Melittobia_ feeds indiscriminately upon the
bee and parasite.

Although the _Melittobia_ does not make such wholesale destruction as
is wrought by the earwig when it gets into a nest, it does more damage
to the bee, on account of its great numbers. Some three or four females
will lay a great quantity of eggs within a nest, and from those eggs a
hundred of the young will be developed. When the larvae are fully grown,
they quit their hold of their prey, and fall to the bottom of the cell,
where they lie until they have assumed the perfect form. They then
burst forth, together with those of the bee that may have escaped their
attacks.]

An interesting account is given by Reaumur of another mason-bee
(_Megachile muraria_), not a native of Britain, selecting earthy sand,
grain by grain; her glueing a mass of these together with saliva, and
building with them her cells from the foundation. But the cells of
the Greenwich Park nest were apparently composed of the mortar of the
brick wall; though the external covering seems to have been constructed
as Reaumur describes his nest, with the occasional addition of small
stones.

About the middle of May, 1829, we discovered the mine from which all
the various species of mason-bees in the vicinity seemed to derive
materials for their nests. (J. R.) It was a bank of brown clay, facing
the east, and close by the margin of the river Ravensbourn, at Lee,
in Kent. The frequent resort of the bees to this spot attracted the
attention of some workmen, who, deceived by their resemblance to
wasps, pointed it out as a wasps' nest; though they were not a little
surprised to see so numerous a colony at this early season. As the
bees had dug a hole in the bank, where they were incessantly entering
and reappearing, we were of opinion that they were a peculiar sort of
the social earth-bees (_Bombi_). On approaching the spot, however, we
remarked that the bees were not alarmed, and manifested none of the
irritation usual in such cases, the consequence of jealous affection
for their young. This led us to observe their operations more minutely;
and we soon discovered that on issuing from the hole each bee carried
out in its mandibles a piece of clay. Still supposing that they
were social earth-bees, we concluded that they were busy excavating
a hollow for their nest, and carrying off the refuse to prevent
discovery. The mouth of the hole was overhung, and partly concealed,
by a large pebble. This we removed, and widened the entrance of the
hole, intending to dig down and ascertain the state of the operations;
but we soon found that it was of small depth. The bees, being scared
away, began scooping out clay from another hole about a yard distant
from the first. Upon our withdrawing a few feet from the first hole,
they returned thither in preference, and continued assiduously digging
and removing the clay. It became obvious, therefore, from their thus
changing place, that they were not constructing a nest, but merely
quarrying for clay as a building material. By catching one of the bees
(_Osmia bicornis_) when it was loaded with its burden, we ascertained
that the clay was not only carefully kneaded, but was also more moist
than the mass from which it had been taken. The bee, therefore, in
preparing the pellet, which was nearly as large as a garden-pea, had
moistened it with its saliva, or some similar fluid, to render it, we
may suppose, more tenacious, and better fitted for building. The reason
of their digging a hole, instead of taking clay indiscriminately from
the bank, appeared to be for the purpose of economizing their saliva,
as the weather was dry, and the clay at the surface was parched and
hard. It must have been this circumstance which induced them to prefer
digging a hole, as it were, in concert, though each of them had to
build a separate nest.

The distance to which they carried the clay was probably considerable,
as there was no wall near, in the direction they all flew towards, upon
which they could build; and in the same direction also, it is worthy
of remark, they could have procured much nearer the very same sort of
clay. Whatever might be the cause of their preference, we could not
but admire their extraordinary industry. It did not require more than
half a minute to knead one of the pellets of clay; and, from their
frequent returns, probably not more than five minutes to carry it to
the nest, and apply it where wanted. From the dryness of the weather,
indeed, it was indispensable for them to work rapidly, otherwise the
clay could not have been made to hold together. The extent of the whole
labour of forming a single nest may be imagined, if we estimate that
it must take several hundred pellets of clay for its completion. If a
bee work fourteen or fifteen hours a-day, therefore, carrying ten or
twelve pellets to its nest every hour, it will be able to finish the
structure in about two or three days; allowing some hours of extra time
for the more nice workmanship of the cells in which the eggs are to be
deposited, and the young grubs reared.

That the construction of such a nest is not a merely agreeable exercise
to the mason-bee has been sufficiently proved by M. Du Hamel. He has
observed a bee (_Megachile muraria_) less careful to perform the
necessary labour for the protection of her offspring than those we
have described, but not less desirous of obtaining this protection,
attempt to usurp the nest which another had formed. A fierce battle
was invariably the consequence of this attempt; for the true mistress
would never give place to the intruder. The motive for the injustice
and the resistance was an indisposition to further labour. The trial of
strength was probably, sometimes, of as little use in establishing the
right as it is amongst mankind; and the proper owner, exhausted by her
efforts, had doubtless often to surrender to the dishonest usurper.

The account which Reaumur has given of the operations of this class
of bees differs considerably from that which we have here detailed;
from the species being different, or from his bees not having been able
to procure moist clay. On the contrary, sand was the chief material
used by the mason-bees (_Megachile muraria_); which they had the
patience to select from the walks of a garden, and knead into a paste
or mortar, adapted to their building. They had consequently to expend
a much greater quantity of saliva than our bees (_Osmia bicornis_),
which worked with moist clay. Reaumur, indeed, ascertained that every
individual grain of sand is moistened previous to its being joined to
the pellet, in order to make it adhere more effectually. The tenacity
of the mass is, besides, rendered stronger, he tells us, by adding a
proportion of earth or garden-mould. In this manner, a ball of mortar
is formed, about the size of a small shot, and carried off to the nest.
When the structure of this is examined, it has all the appearance
externally of being composed of earth and small stones or gravel. The
ancients, who were by no means accurate naturalists, having observed
bees carrying pellets of earth and small stones, supposed that they
employed these to add to their weight, in order to steady their flight
when impeded by the wind.

The nests thus constructed appear to have been more durable edifices
than those which have fallen under our observation;--for Reaumur says
they were harder than many sorts of stone, and could scarcely be
penetrated with a knife. Ours, on the contrary, do not seem harder
than a piece of sun-baked clay, and by no means so hard as brick. One
circumstance appeared inexplicable to Reaumur and his friend Du Hamel,
who studied the operations of these insects in concert. After taking a
portion of sand from one part of the garden-walk, the bees usually took
another portion from a spot almost twenty and sometimes a hundred paces
off, though the sand, so far as could be judged by close examination,
was precisely the same in the two places. We should be disposed to
refer this more to the restless character of the insect than to any
difference in the sand. We have observed a wasp paring the outside of
a plank, for materials to form its nest; and though the plank was as
uniform in the qualities of its surface, nay, probably more so than the
sand could be, the wasp fidgeted about, nibbling a fibre from one, and
a fibre from another portion, till enough was procured for one load. In
the same way, the whole tribe of wasps and bees flit restlessly from
flower to flower, not unfrequently revisiting the same blossom, again
and again, within a few seconds. It appears to us, indeed, to be far
from improbable, that this very restlessness and irritability may be
one of the springs of their unceasing industry.

By observing, with some care, the bees which we found digging the clay,
we discovered one of them (_Osmia bicornis_) at work upon a nest, about
a gunshot from the bank. The place it had chosen was the inner wall of
a coal-house, facing the south-west, the brick-work of which was but
roughly finished. In an upright interstice of half an inch in width,
between two of the bricks, we found the little architect assiduously
building its walls. The bricklayer's mortar had either partly fallen
out, or been removed by the bee, who had commenced building at the
lower end, and did not build downwards, as the social wasps construct
their cells.

The very different behaviour of the insect here, and at the quarry,
struck us as not a little remarkable. When digging and preparing the
clay, our approach, however near, produced no alarm; the work went on
as if we had been at a distance; and though we were standing close to
the hole, this did not scare away any of the bees upon their arrival
to procure a fresh load. But if we stood near the nest, or even in the
way by which the bee flew to it, she turned back or made a wide circuit
immediately, as if afraid to betray the site of her domicile. We even
observed her turning back, when we were so distant that it could not
reasonably be supposed she was jealous of us; but probably she had
detected some prowling insect depredator, tracking her flight with
designs upon her provision for her future progeny. We imagined we could
perceive not a little art in her jealous caution, for she would alight
on the tiles as if to rest herself; and even when she had entered the
coal-house, she did not go directly to her nest, but again rested on a
shelf, and at other times pretended to examine several crevices in the
wall, at some distance from the nest. But when there was nothing to
alarm her, she flew directly to the spot, and began eagerly to add to
the building.

It is in instances such as these, which exhibit the adaptation
of instinct to circumstances, that our reason finds the greatest
difficulty in explaining the governing principle of the minds of the
inferior animals. The mason-bee makes her nest by an invariable rule;
the model is in her mind, as it has been in the mind of her race from
their first creation: they have learnt nothing by experience. But
the mode in which they accomplish this task varies according to the
situations in which they are placed. They appear to have a glimmering
of reason, employed as an accessary and instrument of their instinct.

[Illustration: Cells of Mason-Bees, built, in the first and second
figures, by _Osmia bicornis_ between bricks, and in the third, by
_Megachile muraria_ in the fluting of an old pilaster.--About half the
natural size.]

The structure, when finished, consisted of a wall of clay supported by
two contiguous bricks, enclosing six chambers, within each of which
a mass of pollen, rather larger than a cherry-stone, was deposited,
together with an egg, from which in due time a grub was hatched.
Contrary to what has been recorded by preceding naturalists with
respect to other mason-bees, we found the cells in this instance quite
parallel and perpendicular; but it may also be remarked, that the bee
itself was a species altogether different from the one which we have
described above as the _Anthophora retusa_, and agreed with the figure
of the one we caught quarrying the clay--(_Osmia bicornis_).

[In Mr. F. Smith's elaborate catalogue of the British hymenoptera there
is a most interesting account of the habits of this insect, which is
the most abundant species of the genus, and is spread not only over the
whole of England, but over the continent, being found as far south as
Italy and as far north as Lapland.

"In a hilly country, or at the sea-side, it chooses the sunny side of
cliffs or sandy banks in which to form its burrows, but in cultivated
districts, particularly if the soil be clayey, it selects a decayed
tree, preferring the stump of an old willow. It lays up a store of
pollen and honey for the larvae, which when full grown, spins a tough
dark brown cocoon, in which they remain in the larval state until the
autumn, when the majority change to pupae, and soon arrive at their
perfect condition. Many, however, pass the winter in the larva state.
In attempting to account for so remarkable a circumstance, all must
be conjecture, but it is not of unfrequent occurrence. This species
frequently makes its burrows in the mortar of old walls."

Another species (_Osmia bicolor_) sometimes makes its cells in very
peculiar situations. When obliged to have recourse to its natural
powers, it uses its limbs right well, attacks the hard sandy banks,
and works at them with the greatest perseverance. But it will not work
one stroke where it can avoid the necessity, and in many cases, it
contrives to avoid work with much ingenuity.

Lying hidden under hedges, bushes, grass, and herbage, are sure to be
shells of various snails, such as the common garden-snail, and the
banded-snail, whose diversified shell is the delight of children. These
shells the bee thinks are as good as ready-made burrows, and she uses
them accordingly.

She goes to the end of the shell, carrying her materials with her, and
then builds a cell, and fills it with pollen and honey. Another cell
is then made, and yet another, until the shell is nearly filled. As
the shell widens, the _Osmia_ places two cells side by side, and when
the insect has worked within a short distance of the mouth, she places
the cells horizontally, so as to fill up the space. There are several
specimens of these curious habitations in the British Museum.

When the whole series of cells is completed, the bee closes up the
entrance with little morsels of earth, bits of stick and little stones,
all strongly glued together with some very adhesive substance.

Another species (_Osmia parietina_) has much simpler habits, and is
much easier satisfied with a dwelling. This insect merely looks out for
a flattish stone lying on the ground, and crawls under it to see if
there is any hollow. If so, it attaches the cocoons to the stone and
leaves them. On one stone, seen in the British Museum, no less than two
hundred and thirty cocoons were placed, although the stone is only ten
inches in length by six in width.

This insect is almost wholly confined to the north of England.]

There was one circumstance attending the proceedings of this mason-bee
which struck us not a little, though we could not explain it to our own
satisfaction. Every time she left her nest for the purpose of procuring
a fresh supply of materials, she paid a regular visit to the blossoms
of a lilac-tree which grew near. Had these blossoms afforded a supply
of pollen, with which she could have replenished her cells, we could
have easily understood her design; but the pollen of the lilac is not
suitable for this purpose, and that she had never used it was proved
by all the pollen in the cells being yellow, whereas that of the lilac
is of the same pale purple colour as the flowers. Besides, she did not
return immediately from the lilac-tree to the building, but always
went for a load of clay. There seemed to us, therefore, to be only
two ways to explain the circumstance:--she must either have applied
to the lilac-blossoms to obtain a refreshment of honey, or to procure
glutinous materials to mix with the clay.

When employed upon the building itself, the bee exhibited the restless
disposition peculiar to most hymenopterous[P] insects; for she did not
go on with one particular portion of her wall, but ran about from place
to place every time she came to work. At first, when we saw her running
from the bottom to the top of her building, we naturally imagined
that she went up for some of the bricklayer's mortar to mix with her
own materials; but upon minutely examining the walls afterwards, no
lime could be discovered in their structure similar to that which was
apparent in the nest found in the wall of Greenwich Park.

Reaumur mentions another sort of mason-bee, which selects a small
cavity in a stone, in which she forms her nest of garden-mould
moistened with gluten, and afterwards closes the whole with the same
material.

[Illustration: Cells of _Chalicodoma_.]

[In the accompanying illustration is shown a series of cells which are
constructed by an insect which is closely related to the rose-cutter
bee of our own country, to which it bears a close resemblance.

It is a native of South Africa, and its name is _Chalicodoma
coelocerus_. The insect is about half an inch in length, and the colour
of the head and body is black, that of the abdomen being brick red.

The nest is made of mud, which is collected by the patient insect and
stuck against walls, trunks of trees, and similar localities. In this
lump of mud the insect excavates a small number of burrows, each of
which contains several cells. If the reader will refer to the central
burrow, he will see that it is divided into three cells. The specimen
from which this drawing is taken may be seen in the British Museum.

There is another South African insect which makes its mud nest, and
fastens it against trees and walls. This is called _Synagris calida_,
and its colour is almost dingy black, the only exception being the red
tip to the abdomen. The holes seen in the engraving are the apertures
through which the young brood has escaped into the world. The nest is
represented of half its natural size.]

[Illustration]


Mining-Bees.

A very small sort of bees (_Andrenae_), many of them not larger than a
house-fly, dig in the ground tubular galleries little wider than the
diameter of their own bodies. Samouelle says, that all of them seem
to prefer a southern aspect; but we have found them in banks facing
the east, and even the north. Immediately above the spot where we have
described the mason-bees quarrying the clay, we observed several holes,
about the diameter of the stalk of a tobacco-pipe, into which those
little bees were seen passing. The clay here was very hard; and on
passing a straw into the hole as a director, and digging down for six
or eight inches, a very smooth circular gallery was found, terminating
in a thimble-shaped horizontal chamber, almost at right angles to the
entrance and nearly twice as wide. In this chamber there was a ball
of bright yellow pollen, as round as a garden pea, and rather larger,
upon which a small white grub was feeding; and to which the mother
bee had been adding, as she had just entered a minute before with
her thighs loaded with pollen. That it was not the male, the load of
pollen determined; for the male has no apparatus for collecting or
transporting it. The whole labour of digging the nest and providing
food for the young is performed by the female. The females of the
solitary bees have no assistance in their tasks. The males are idle;
and the females are unprovided with labourers, such as the queens of
the hive command.

[Illustration: Cell of Mining-Bee (_Andrena_).--About half the natural
size.]

Reaumur mentions that the bees of this sort, whose operations he
had observed, piled up at the entrance of their galleries the earth
which they had scooped out from the interior; and when the grub was
hatched, and properly provided with food, the earth was again employed
to close up the passage, in order to prevent the intrusion of ants,
ichneumon-flies, or other depredators. In those which we have observed,
this was not the case; but every species differs from another in some
little peculiarity, though they agree in the general principles of
their operations.

[The genus Andrena is an exceedingly large one, nearly seventy species
being acknowledged in England alone. They choose various situations
for their nest; a very favourite situation is a hard-trodden pathway;
into this the bees burrow for some six or seven inches, and often drive
their tunnels to a depth of ten inches. Digging up these habitations
is not a very easy task, because the tunnel does not run straight, but
turns aside when a stone or any similar obstacle comes in the way, and
in getting out the stone the burrow is mostly broken. The only method
of digging out the nest successfully is either by pushing a small twig
up the hole, and using it as a guide, or by filling the entire hole
with cotton wool, so as to prevent the earth from falling in.

The commonest species is _Andrena albicans_. Its length is rather
less than half an inch, and its colour is black, with a thick coating
of rich red hair on the upper part of the thorax. This species is
plentiful on the continent, and is found as far south as Italy. But it
is equally capable of enduring great cold, as it has been captured in
the Arctic regions. Sometimes the bee will not trouble itself to make a
number of separate burrows, but will drive short supplementary tunnels
from the side of the first burrow, so that they all open into one
common entrance.

The Andrenae are remarkable for the parasites with which they are
infested, the most curious of which is that tiny strepsipterous insect
called the Stylops.

One of the Andrenae, called _Colletes Daviesana_, is remarkable for the
character of its burrow. Like many of the insects which have already
been described, it seems indifferent whether it burrows in sand-banks
or into the mortar of walls, provided that in the latter case the
mortar is soft and friable.

The insect burrows a hole which is very deep in proportion to its size,
the little bee being only the third of an inch in length, and the
burrows some eight or ten inches in depth. When the mother _Colletes_
has finished her tunnel, she lines the end of it with a thin kind of
membrane, which has been well compared by Mr. F. Smith to goldbeater's
skin. This lining is intended to enable the bee to store honey in the
cell, as, if there were no such protection, the honey would soak in the
ground and be lost.

Having stored up enough food for a single offspring, she shuts it off
by a partition of the same membranous substance as the lining. Her next
care is to make a thimble-like cup at the end, so as to have a double
lining where the honey is to come, and then she puts a fresh supply in
the new cell. This cell is then closed, and the bee proceeds with her
work until she has made from six to eight cells in a single burrow.
This insect suffers terribly from the depredations of the earwig, which
completely empties the burrow both of food and of inhabitants. The
colour of the insect is black, with a little reddish down on the upper
part of the thorax, and some white on the legs. The abdomen is shining
black, but each segment has a very narrow band of reddish down on its
edge.

In 1850, Mr. F. Smith, to whose works such constant reference has been
made, undertook the study of a genus of mining-bees belonging to this
family. The species which he chiefly watched is _Halictus morio_, and
his observations are peculiarly valuable, as showing the wonderful
manner in which the economy of the race is managed. It is known that in
these and many other insects, the pregnant females pass the winter in
a state of hibernation, and begin to work in the following spring, and
that therefore some arrangement must be needful that a supply of such
queens should be kept up.

Mr. Smith found the case to stand thus. Early in April, the females
appeared abundantly, and could be seen until June, but not a single
male was to be found. During June and July, almost all the _Halicti_
had disappeared, the reason being, that the queens had made their
burrows, laid their eggs, stocked their cells, and then died, the
duties of their life having been fulfilled. In the middle of August,
the males began to appear, and in September the females of the first
brood came out. They immediately set to work at their burrows, and
laid their eggs. The ground, thoroughly warmed by the summer sun, soon
hastened the young through their changes, and in an incredibly short
time the insects of the second brood made their appearance. The females
of this brood meet their mates, and then hide themselves until the
following spring.

As in the case of Andrenae, several tunnels are often made with one
common entrance. The insect is very small, scarcely exceeding the
sixth of an inch in length. The head and thorax are a dark green, the
abdomen is white, and the legs are covered with silvery hairs. It is a
plentiful insect, and is found haunting the holes of old walls.

Passing to another family of British mining-bees, we come to one
species that is remarkable not only for its form, but for its economy.
This is the _Eucera longicornis_, the only known species that inhabits
England. In form it is chiefly remarkable from the fact that the
antennae of the male are as long as the entire body. The pupa of this
insect is enclosed in a thin membrane, and when the male insect is
about to emerge from its pupal shell, it has recourse to a rather
curious expedient. At the base of the first joint of the front feet
there is a bold notch. When the insect wishes to remove the thin
membranous pellicle which envelopes the antennae, it lays these organs
in the notch, draws them through, and thus easily strips off the
pellicle. The antennae are most beautifully formed, the surface of each
joint being marked with an elaborate pattern like net-work, so that
they form beautiful objects for the microscope.

The soil preferred by the _Eucera_ is of a clayey nature. When it has
completed the burrow, it presses the soil at the extremity with all its
might, and smooths it so carefully that the burrow becomes capable of
holding honey without needing any lining. The insect is generally found
about the end of May or beginning of June, and in some places is found
in great numbers. The ground colour of the insect is black, but the
body is covered with a coating of short dun hairs. The length rather
exceeds half an inch.]




_CHAPTER III._

CARPENTER-BEES; CARPENTER-WASPS; UPHOLSTERER-BEES.


Carpenter-Bees.

Among the solitary bees are several British species, which come under
that class called carpenter-bees by M. Reaumur, from the circumstance
of their working in wood, as the mason-bees work in stone. We have
frequently witnessed the operations of these ingenious little workers,
who are particularly partial to posts, palings, and the wood-work of
houses which has become soft by beginning to decay. Wood actually
decayed, or affected by dry-rot, they seem to reject as unfit for their
purposes; but they make no objections to any hole previously drilled,
provided it be not too large; and, like the mason-bees, they not
unfrequently take possession of an old nest, a few repairs being all
that in this case is necessary.

When a new nest is to be constructed, the bee proceeds to chisel
sufficient space for it out of the wood with her jaws. We say _her_,
because the task in this instance, as in most others of solitary bees
and wasps, devolves solely upon the female, the male taking no concern
in the affair, and probably being altogether ignorant that such a work
is going forward. It is, at least, certain that the male is never
seen giving his assistance, and he seldom, if ever, approaches the
neighbourhood. The female carpenter-bee has a task to perform no less
arduous than the mason-bee; for though the wood may be tolerably soft,
she can only cut out a very small portion at a time. The successive
portions which she gnaws off may be readily ascertained by an observer,
as she carries them away from the place. In giving the history of a
mason-wasp (_Odynerus_), at page 22, we remarked the care with which
she carried to a distance little fragments of brick, which she
detached in the progress of excavation. We have recently watched a
precisely similar procedure in the instance of a carpenter-bee forming
a cell in a wooden post. (J. R.) The only difference was, that the bee
did not fly so far away with her fragments of wood as the wasp did; but
she varied the direction of her flight every time: and we could observe
that, after dropping, the chip of wood which she had carried off, she
did not return in a direct line to her nest, but made a circuit of some
extent before wheeling round to go back.

On observing the proceedings of this carpenter-bee next day, we found
her coming in with balls of pollen on her thighs; and on tracing her
from the nest into the adjacent garden, we saw her visiting every
flower which was likely to yield her a supply of pollen for her future
progeny. This was not all; we subsequently saw her taking the direction
of the clay quarry frequented by the mason-bees, as we have mentioned
in page 41, where we recognised her loading herself with a pellet of
clay, and carrying it into her cell in the wooden post. We observed
her alternating this labour for several days, at one time carrying
clay, and at another pollen; till at length she completed her task, and
closed the entrance with a barricade of clay, to prevent the intrusion
of any insectivorous depredator, who might make prey of her young; or
of some prying parasite, who might introduce its own eggs into the nest
she had taken so much trouble to construct.

Some days after it was finished, we cut into the post, and exposed this
nest to view. It consisted of six cells of a somewhat square shape, the
wood forming the lateral walls; and each was separated from the one
adjacent by a partition of clay, of the thickness of a playing card.
The wood was not lined with any extraneous substance, but was worked as
smooth as if it had been chiseled by a joiner. There were five cells,
arranged in a very singular manner--two being almost horizontal, two
perpendicular, and one oblique.

The depth to which the wood was excavated in this instance was
considerably less than what we have observed in other species which dig
perpendicular galleries several inches deep in posts and garden-seats;
and they are inferior in ingenuity to the carpentry of a bee described
by Reaumur (_Xylocopa violacea_), which has not been ascertained to be
a native of Britain, though a single indigenous species of the genus
has been doubtingly mentioned, and is figured by Kirby and Spence, in
their valuable 'Monographia.' If it ever be found here, its large size
and beautiful violet- wings will render mistakes impossible.

[Illustration: Cells of Carpenter-Bees, excavated in an old post.

In fig. A the cells contain the young grubs; in fig. B the cells are
empty. Both figures are shown in section, and about half their natural
size.]

The violet carpenter-bee usually selects an upright piece of wood,
into which she bores obliquely for about an inch; and then, changing
the direction, works perpendicularly, and parallel to the sides of
the wood, from twelve or fifteen inches, and half an inch in breadth.
Sometimes the bee is contented with one or two of these excavations; at
other times, when the wood is adapted to it, she scoops out three or
four--a task which sometimes requires several weeks of incessant labour.

[Illustration: A represents a part of an espalier prop, tunnelled in
several places by the violet Carpenter-Bee: the stick is split, and
shows the nests and passages by which they are approached. B, a portion
of the prop, half the natural size. C, a piece of thin stick, pierced
by the Carpenter-Bee, and split, to show the nests. D, perspective view
of one of the partitions. E, Carpenter-Bee (_Xylocopa violacea_). F,
Teeth of the Carpenter-Bee, greatly magnified; _a_, the upper side;
_b_, the lower side.]

The tunnel in the wood, however, is only one part of the work; for
the little architect has afterwards to divide the whole into cells,
somewhat less than an inch in depth. It is necessary, for the proper
growth of her progeny, that each should be separated from the other,
and be provided with adequate food. She knows, most exactly, the
quantity of food which each grub will require during its growth; and
she therefore does not hesitate to cut it off from any additional
supply. In constructing her cells, she does not employ clay, like the
bee which we have mentioned above, but the sawdust, if we may call
it so, which she has collected in gnawing out the gallery. It would
not, therefore, have suited her design to scatter this about, as our
carpenter-bee did. The violet-bee, on the contrary, collects her
gnawings into a little store-heap for future use, at a short distance
from her nest. She proceeds thus:--At the bottom of her excavation she
deposits an egg, and over it fills a space nearly an inch high with
the pollen of flowers, made into a paste with honey. She then covers
this over with a ceiling composed of cemented sawdust, which also
serves for the floor of the next chamber above it. For this purpose she
cements round a wall a ring of wood-chips taken from her store-heap;
and within this ring forms another, gradually contracting the diameter
till she has constructed a circular plate, about the thickness of
a crown-piece, and of considerable hardness. This plate of course
exhibits concentric circles, somewhat similar to the annual circles
in the cross section of a tree. In the same manner she proceeds till
she has completed ten or twelve cells; and then she closes the main
entrance with a barrier of similar materials.

Let us compare the progress of this little joiner with a human
artisan--one who has been long practised in his trade, and has the most
perfect and complicated tools for his assistance. The bee has learnt
nothing by practice; she makes her nest but once in her life, but it is
then as complete and finished as if she had made a thousand. She has
no pattern before her--but the Architect of all things has impressed a
plan upon her mind, which she can realize without scale or compasses.
Her two sharp teeth are the only tools with which she is provided for
her laborious work; and yet she bores a tunnel, twelve times the length
of her own body, with greater ease than the workman who bores into the
earth for water, with his apparatus of augurs adapted to every soil.
Her tunnel is clean and regular; she leaves no chips at the bottom,
for she is provident of her materials. Further, she has an exquisite
piece of joinery to perform when her ruder labour is accomplished. The
patient bee works her rings from the circumference to the centre, and
she produces a shelf, united with such care with her natural glue, that
a number of fragments are as solid as one piece.

The violet carpenter-bee, as may be expected, occupies several weeks
in these complicated labours; and during that period she is gradually
depositing her eggs, each of which is successively to become a grub,
a pupa, and a perfect bee. It is obvious, therefore, as she does not
lay all her eggs in the same place--as each is separated from the
other by a laborious process--that the egg which is first laid will be
the earliest hatched; and that the first perfect insect, being older
than its fellows in the same tunnel, will strive to make its escape
sooner, and so on of the rest. The careful mother provides for this
contingency. She makes a lateral opening at the bottom of the cells;
for the teeth of the young bees would not be strong enough to pierce
the outer wood, though they can remove the cemented rings of sawdust in
the interior. Reaumur observed these holes, in several cases; and he
further noticed another external opening opposite to the middle cell,
which he supposed was formed, in the first instance, to shorten the
distance for the removal of the fragments of wood in the lower half of
the building.

       *       *       *       *       *

That bees of similar habits, if not the same species as the violet-bee,
are indigenous to this country, is proved by Grew, who mentions, in his
'Rarities of Gresham College,' having found a series of such cells in
the middle of the pith of an elder branch, in which they were placed
lengthwise, one after another, with a thin boundary between each. As he
does not, however, tell us that he was acquainted with the insect which
constructed these, it might as probably be allied to the _Ceratina
albilabris_, of which Spinola has given so interesting an account in
the 'Annales du Museum d'Histoire Naturelle' (x. 236). This noble and
learned naturalist tells us, that one evening he perceived a female
ceratina alight on the branch of a bramble, partly withered, and of
which the extremity had been broken; and, after resting a moment,
suddenly disappear. On detaching the branch, he found that it was
perforated, and that the insect was in the very act of excavating a
nidus for her eggs. He forthwith gathered a bundle of branches, both
of the bramble and the wild-rose, similarly perforated, and took them
home to examine them at leisure. Upon inspection, he found that the
nests were furnished like those of the same tribe, with balls of pollen
kneaded with honey, as a provision for the grubs.

The female ceratina selects a branch of the bramble or wild-rose which
has been accidentally broken, and digs into the pith only, leaving the
wood and bark untouched. Her mandibles, indeed, are not adapted for
gnawing wood; and, accordingly, he found instances in which she could
not finish her nest in branches of the wild-rose, where the pith was
not of sufficient diameter.

The insect usually makes her perforation a foot in depth, and divides
this into eight, nine, or even twelve cells, each about five lines
long, and separated by partitions formed by the gnawings of the pith,
cemented by honey, or some similar glutinous fluid, much in the same
manner with the _Xylocopa violacea_, which we have already described.

[This species is probably _Ceratina caerulea_, as the second species,
_C. albilabris_, seems to have little claim to be considered as a
British insect. It is plentiful in spots where it resides, but is very
local. It can best be found by collecting all the specimens of bramble
branches that have holes bored into the pith.

Mr. F. Smith says of this tiny bee, "Some years ago I observed a small
bee most industriously employed in excavating a dead bramble stick. My
attention was directed to the circumstance from observing some of the
fallen pieces of pith on the ground immediately beneath. Occasionally
fresh quantities of dust were pushed out. At length, the little
creature came out of the stick as if to rest, and after sunning itself
for a few minutes, it re-entered, and again commenced its labours.
Later in the day, after stopping up the entrance, I cut off the branch
and found in it a male and female ceratina."

The ceratina is only the sixth of an inch in length, and is deep
shining blue in colour.

There are many other species of British bees which frequent the stems
of bramble and other trees. One of them is known as _Prosopis signata_.
The cells made by the bees of this genus are lined with a membrane, and
are stocked with liquid honey. Some species will not take the trouble
of boring a tunnel for themselves, but will make use of hollow stones,
or similar localities, and place in them the silk-covered cocoons.

There are species of that versatile genus _Osmia_ (_O. leucomelana_),
in the habit of burrowing into dead bramble branches. The mother
insect bores a hole some six inches in length, throwing the pieces of
pith away, and then, depositing at the bottom an egg and a supply of
food, she forms a cell by fixing across the burrow a stopper made of
masticated leaves.

The stopper retains its place firmly, because the bee does not eat
away the whole of the pith, but alternately widens and contracts the
diameter of the burrow, each contracted portion being the termination
of a cell. The perfect insect appears in the early summer of the
following year.]


Carpenter-Wasps.

[Illustration: A, B, represent sections of old wooden posts, with
the cells of the Carpenter-Wasp. In fig. A the young grubs are shown
feeding on the insects placed there for their support by the parent
wasp. The cells in fig. B contain cocoons. C, Carpenter-Wasp, natural
size. D, cocoon of a Carpenter-Wasp, composed of sawdust and wings of
insects.]

As there are mason-wasps similar in economy to mason-bees, so are there
solitary carpenter-wasps which dig galleries in timber, and partition
them out into several cells by means of the gnawings of the wood which
they have detached. This sort of wasp is of the genus _Eumenes_. The
wood selected is generally such as is soft, or in a state of decay; and
the hole which is dug in it is much less neat and regular than that of
the carpenter-bees, while the division of the chambers is nothing more
than the rubbish produced during the excavation.

The provision which is made for the grub consists of flies or gnats
piled into the chamber, but without the nice order remarkable in
the spiral columns of green caterpillars provided by the mason-wasp
(_Odynerus murarius_). The most remarkable circumstance is, that in
some of the species, when the grub is about to go into the pupa state,
it spins a case (a cocoon), into which it interweaves the wings of the
flies whose bodies it has previously devoured. In other species, the
gnawings of the wood are employed in a similar manner.

[Some of the solitary wasps are also carpenters, and the genus _Crabro_
has several species which are classed under this head. There is, for
example, _Crabro clavipes_, a little black insect with red and black
abdomen, that burrows into dead bramble sticks, boring out the pith,
and forming a series of cells in the narrow tube thus made. Sometimes
this insect bores into decaying wood, but its general home is the
bramble-stick. The same habits are common to several other British
species of this genus, and the reader will find that old, decaying
willow trees are chiefly visited by these pretty little insects. Their
store of food, which they lay up for their young, mostly consists of
dipterous insects, and various species of gnats are used for this
purpose.

Another of the carpenter-wasps (_Pemphredon lugubris_) is really a
useful insect. It makes its burrows in posts, rails, and similar
localities, and provides its future young with a large stock of
aphides. It has been seen to settle on a rose-bush, scrape off the
branches a number of aphides, form them into a ball, and carry them off
between its head and front legs.

The colour of this insect is dull black, from which circumstance it
derives its name of _lugubris._ The head is large, and squared, and the
abdomen is attached to the thorax by a large footstalk. Its length is
about half an inch. It is a very common insect, and is believed to be
the only British representation of its genus.

Several species do not take the trouble to form a burrow for
themselves, but content themselves with building in holes ready made
for them. Straws are favourite resorts of such insects, and in thatched
buildings the straws of the roof are often filled with their cells.

One of these insects is a very little species, barely a quarter of an
inch in length. Its colour is black, with some silver white hair on
the face, and the legs are paler than the body. The abdomen has a long
footstalk. Its scientific name is _Psen pallipes_. Like the insect
which has just been described, it provisions its young with aphides.]


Upholsterer-Bees.

In another part of this volume we shall see how certain caterpillars
construct abodes for themselves, by cutting off portions of the
leaves or bark of plants, and uniting them by means of silk into a
uniform and compact texture; but this scarcely appears so wonderful
as the prospective labours of some species of bees for the lodgment
of their progeny. We allude to the solitary bees, known by the name
of the leaf-cutting bees, but which may be denominated more generally
_upholsterer-bees_, as there are some of them which use other materials
beside leaves.

One species of our little upholsterers has been called the poppy-bee
(_Osmia papaveris_, Latr.), from its selecting the scarlet petals of
the poppy as tapestry for its cells. Kirby and Spence express their
doubts whether it is indigenous to this country: we are almost certain
that we have seen the nests in Scotland. (J. R.) At Largs, in Ayrshire,
a beautiful sea-bathing village on the Firth of Clyde, in July, 1814,
we found in a footpath a great number of the cylindrical perforations
of the poppy-bee. [In his catalogue of British Hymenoptera, Mr. F.
Smith makes the following remarks with regard to this insect. "The
poppy-bee, _Anthocopa papaveris_, is closely allied to this genus
(_Osmia_), and may indeed be placed before it as a connecting link
with the _Osmia_. This interesting insect (_l'abeille Tapissiere_),
of Reaumur, has been supposed to inhabit this country, specimens
having been placed in the collection at the British Museum. But it was
with much regret that I discovered, when engaged upon the catalogue
of British bees for the Museum, and had occasion to examine each
individual specimen with care, that in the first place there was no
satisfactory evidence of the locality, and that in the next place, all
the males associated with the series were those of _Osmia adunca_, of
Panzear." For these reasons, this species has been excluded from the
list of British bees.] Reaumur remarked that the cells of this bee
which he found at Bercy, were situated in a northern exposure, contrary
to what he had remarked in the mason-bee, which prefers the south. The
cells at Largs, however, were on an elevated bank, facing the south,
near Sir Thomas Brisbane's observatory. With respect to exposure,
indeed, no certain rule seems applicable; for the nests of mason-bees
which we found on the wall of Greenwich Park faced the north-east, and
we have often found carpenter-bees make choice of a similar situation.
In one instance, we found carpenter-bees working indifferently on the
north-east and south-west side of the same post.

As we did not perceive any heaps of earth near the holes at Largs,
we concluded that it must either have been carried off piecemeal
when they were dug, or that they were old holes re-occupied (a
circumstance common with bees), and that the rubbish had been trodden
down by passengers. Reaumur, who so minutely describes the subsequent
operations of the bee, says nothing respecting its excavations. One
of these holes is about three inches deep, gradually widening as it
descends, till it assumes the form of a small Florence flask. The
interior of this is rendered smooth, uniform, and polished, in order
to adapt it to the tapestry with which it is intended to be hung, and
which is the next step in the process.

The material used for tapestry by the insect upholsterer is supplied
by the flower-leaves of the scarlet field-poppy, from which she
successively cuts off small pieces of an oval shape, seizes them
between her legs, and conveys them to the nest. She begins her work at
the bottom, which she overlays with three or four leaves in thickness,
and the sides have never less than two. When she finds that the piece
she has brought is too large to fit the place intended, she cuts off
what is superfluous, and carries away the shreds. By cutting the
fresh petal of a poppy with a pair of scissors, we may perceive the
difficulty of keeping the piece free from wrinkles and shrivelling;
but the bee knows how to spread the pieces which she uses as smooth as
glass.

When she has in this manner hung the little chamber all around with
this splendid scarlet tapestry, of which she is not sparing, but
extends it even beyond the entrance, she then fills it with the pollen
of flowers mixed with honey, to the height of about half an inch. In
this magazine of provisions for her future progeny she lays an egg, and
over it folds down the tapestry of poppy-petals from above. The upper
part is then filled in with earth; but Latreille says he has observed
more than one cell constructed in a single excavation. This may account
for Reaumur's describing them as sometimes seven inches deep; a
circumstance which Latreille, however, thinks very surprising.

It will, perhaps, be impossible ever to ascertain, beyond a doubt,
whether the tapestry-bee is led to select the brilliant petals of the
poppy from their colour, or from any other quality they may possess, of
softness or of warmth, for instance. Reaumur thinks that the largeness,
united with the flexibility of the poppy-leaves, determines her
choice. Yet it is not improbable that her eye may be gratified by the
appearance of her nest; that she may possess a feeling of the beautiful
in colour, and may look with complacency upon the delicate hangings
of the apartment which she destines for her offspring. Why should not
an insect be supposed to have a glimmering of the value of ornament?
How can we pronounce, from our limited notion of the mode in which the
inferior animals think and act, that their gratifications are wholly
bounded by the positive utility of the objects which surround them? Why
does a dog howl at the sound of a bugle, but because it offends his
organ of hearing?--and why, therefore, may not a bee feel gladness in
the brilliant hues of her scarlet drapery, because they are grateful to
her organs of sight? All these little creatures work, probably, with
more neatness and finish than is absolutely essential for comfort; and
this circumstance alone would imply that they have something of taste
to exhibit, which produces to them a pleasurable emotion.

The tapestry-bee is, however, content with ornamenting the interior
only of the nest which she forms for her progeny. She does not
misplace her embellishments with the error of some human artists. She
desires security as well as elegance; and, therefore, she leaves no
external traces of her operations. Hers is not a mansion rich with
columns and friezes without, but cold and unfurnished within, like the
desolate palaces of Venice. She covers her tapestry quite round with
the common earth; and leaves her eggs enclosed in their poppy-case
with a certainty that the outward show of her labours will attract no
plunderer.

The poppy-bee may be known by its being rather more than a third of
an inch long, of a black colour, studded on the head and back with
reddish-grey hairs; the belly being grey and silky, and the rings
margined with grey above, the second and third having an impressed
transversal line.

       *       *       *       *       *

A species of solitary bee (_Anthidium manicatum_, Fabricius), by no
means uncommon with us, forms a nest of a peculiarly interesting
structure. Kirby and Spence say, that it does not excavate holes, but
makes choice of the cavities of old trees, key-holes, and similar
localities; yet it is highly probable, we think, that it may sometimes
scoop out a suitable cavity when it cannot find one; for its mandibles
seem equally capable of this, with those of any of the carpenter or
mason-bees.

Be this as it may, the bee in question having selected a place suitably
sheltered from the weather, and from the intrusion of depredators,
proceeds to form her nest, the exterior walls of which she forms of the
wool of pubescent plants, such as rose-campion (_Lychnis coronaria_),
the quince (_Pyrus cydonia_), cats-ears (_Stachys lunata_), &c. "It
is very pleasant," says Mr. White, of Selborne, "to see with what
address this insect strips off the down, running from the top to the
bottom of the branch, and shaving it bare with all the dexterity of
a hoop-shaver. When it has got a vast bundle, almost as large as
itself, it flies away, holding it secure between its chin and its
fore-legs."[Q] The material is rolled up like a ribbon; and we possess
a specimen in which one of these rolls still adheres to a rose-campion
stem, the bee having been scared away before obtaining her load.

The manner in which the cells of the nest are made seems not to be
very clearly understood. M. Latreille says, that, after constructing
her nest of the down of quince-leaves, she deposits her eggs, together
with a store of paste, formed of the pollen of flowers, for nourishing
the grubs. Kirby and Spence, on the other hand, tell us, that "the
parent bee, _after_ having constructed her cells, laid an egg in each,
and filled them with a store of suitable food, plasters them with a
covering of vermiform masses, apparently composed of honey and pollen;
and having done this, aware, long before Count Rumford's experiments,
what materials conduct heat most slowly," she collects the down from
woolly plants, and "sticks it upon the plaster that covers her cells,
and thus closely envelops them with a warm coating of down, impervious
to every change of temperature." "From later observations," however,
they are "inclined to think that these cells may possibly, as in the
case of the humble-bee, be in fact formed by the larva previously to
becoming a pupa, after having eaten the provision of pollen and honey
with which the parent bee had surrounded it. The vermicular shape,
however, of the masses with which the cases are surrounded, does not
seem easily reconcilable with this supposition, unless they are
considered as the excrement of the larva."[R]

Whether or not this second explanation is the true one, we have not
the means of ascertaining; but we are almost certain the first is
incorrect, as it is contrary to the regular procedure of insects to
begin with the interior part of any structure, and work outwards. We
should imagine, then, that the down is first spread out into the form
required, and afterwards plastered on the inside to keep it in form,
when probably the grub spins the vermicular cells previous to its
metamorphosis.

It might prove interesting to investigate this more minutely; and as
the bee is by no means scarce in the neighbourhood of London, it might
not be difficult for a careful observer to witness all the details
of this singular architecture. Yet we have repeatedly endeavoured,
but without success, to watch the bees, when loaded with down, to
their nests. The bee may be readily known from its congeners, by its
being about the size of the hive-bee, but more broad and flattened,
blackish-brown above, with a row of six yellow or white spots along
each side of the rings, very like the rose-leaf cutter, and having the
belly covered with yellowish-brown hair, and the legs fringed with long
hairs of a rather lighter colour.

       *       *       *       *       *

[This bee does not bore a tunnel for herself, but occupies that of some
other insect. The nests of this insect are generally to be obtained
from old willows, because these trees are so largely bored by the
goat-moth caterpillar, and afford ample space for the larva. The woolly
substance obtained from the plant is pressed against the sides of the
burrow, so as to form a lining. She then makes a series of cells of a
similar material, and the young larva, when it is about to change into
the pupa state, envelops itself in a silken covering of a brown colour.

It is a curious fact, that the male of this insect is considerably
larger than the female, thus reversing the usual order of things among
insects. Only one species of this bee is known in England.]

A common bee belonging to the family of upholsterers is called the
rose-leaf cutter (_Megachile centuncularis_, Latr.). The singularly
ingenious habits of this bee have long attracted the attention of
naturalists; but the most interesting description is given by Reaumur.
So extraordinary does the construction of their nests appear, that a
French gardener having dug up some, and believing them to be the work
of a magician, who had placed them in his garden with evil intent,
sent them to Paris to his master, for advice as to what should be done
by way of exorcism. On applying to the Abbe Nollet, the owner of the
garden was soon persuaded that the nests in question were the work of
insects; and M. Reaumur, to whom they were subsequently sent, found
them to be the nests of one of the upholsterer-bees, and probably of
the rose-leaf cutter, though the nests in question were made of the
leaves of the mountain ash (_Pyrus aucuparia_).

The rose-leaf cutter makes a cylindrical hole in a beaten pathway,
for the sake of more consolidated earth (or in the cavities of walls
or decayed wood), from six to ten inches deep, and does not throw
the earth dug out from it into a heap, like the Andrenae.[S] In this
she constructs several cells about an inch in length, shaped like a
thimble, and made of cuttings of leaves (not petals), neatly folded
together, the bottom of one thimble-shaped cell being inserted into the
mouth of the one below it, and so on in succession.

[Illustration: Rose-leaf cutter Bees, and Nest lined with rose-leaves.]

It is interesting to observe the manner in which this bee procures
the materials for forming the tapestry of her cells. The leaf of the
rose-tree seems to be that which she prefers, though she sometimes
takes other sorts of leaves, particularly those with serrated margins,
such as the birch, the perennial mercury (_Mercurialis perennis_),
mountain-ash, &c. She places herself upon the outer edge of the
leaf which she has selected, so that its margin may pass between her
legs. Turning her head towards the point, she commences near the
footstalk, and with her mandibles cuts out a circular piece with as
much expedition as we could do with a pair of scissors, and with more
accuracy and neatness than could easily be done by us. As she proceeds,
she keeps the cut portion between her legs, so as not to impede her
progress; and using her body for a _trammel_, as a carpenter would
say, she cuts in a regular curved line. As she supports herself during
the operation upon the portion of the leaf which she is detaching,
it must be obvious, when it is nearly cut off, that the weight of
her body might tear it away, so as to injure the accuracy of its
curvilineal shape. To prevent any accident of this kind, as soon as
she suspects that her weight might tear it, she poises herself on
her wings, till she has completed the incision. It has been said, by
naturalists, that this manoeuvre of poising herself on the wing, is to
prevent her falling to the ground, when the piece gives way; but as no
winged insect requires to take any such precaution, our explanation is
probably the true one.

With the piece which she has thus cut out, held in a bent position
perpendicularly to her body, she flies off to her nest, and fits it
into the interior with the utmost neatness and ingenuity; and, without
employing any paste or glue, she trusts, as Reaumur ascertained, to
the spring the leaf takes in drying, to retain it in its position. It
requires from nine to ten pieces of leaf to form one cell, as they
are not always of precisely the same thickness. The interior surface
of each cell consists of three pieces of leaf, of equal size, narrow
at one end, but gradually widening at the other, where the width
equals half the length. One side of each of the pieces is the serrated
margin of the leaf from which it was cut, and this margin is always
placed outermost, and the cut margin innermost. Like most insects, she
begins with the exterior, commencing with a layer of tapestry, which
is composed of three or four oval pieces, larger in dimensions than
the rest, adding a second and a third layer proportionately smaller.
In forming these, she is careful not to place a joining opposite to a
joining, but with all the skill of a consummate artificer, lays the
middle of each piece of leaf over the margins of the others, so as by
this means both to cover and strengthen the junctions. By repeating
this process, she sometimes forms a fourth or a fifth layer of leaves,
taking care to bend the leaves at the narrow extremity or closed end of
the cell, so as to bring them into a convex shape.

When she has in this manner completed a cell, her next business is to
replenish it with a store of honey and pollen, which, being chiefly
collected from thistles, forms a beautiful rose- conserve. In
this she deposits a single egg, and then covers in the opening with
three pieces of leaf, so exactly circular, that a pair of compasses
could not define their margin with more accuracy. In this manner the
industrious and ingenious upholsterer proceeds till the whole gallery
is filled, the convex extremity of the one fitting into the open end of
the next, and serving both as a basis and as the means of strengthening
it. If, by any accident, the labour of these insects is interrupted or
the edifice deranged, they exhibit astonishing perseverance in setting
it again to rights. Insects, indeed, are not easily forced to abandon
any work which they may have begun.

The monkish legends tell us that St. Francis Xavier, walking one day
in a garden, and seeing an insect, of the _Mantis_ genus, moving along
in its solemn way, holding up its two fore legs, as in the act of
devotion, desired it to sing the praises of God. The legend adds that
the saint immediately heard the insect carol a fine canticle with a
loud emphasis. We want no miraculous voice to record the wonders of the
Almighty hand, when we regard the insect world. The little rose-leaf
cutter, pursuing her work with the nicest mathematical art--using no
artificial instruments to form her ovals and her circles--knowing
that the elastic property of the leaves will retain them in their
position--making her nest of equal strength throughout, by the most
rational adjustment of each distinct part--demands from us something
more than mere wonder; for such an exercise of instinctive ingenuity
at once directs our admiration to the great Contriver, who has so
admirably proportioned her knowledge to her necessities.




_CHAPTER IV._

CARDER-BEES; HUMBLE-BEES; SOCIAL-WASPS.


The bees and wasps, whose ingenious architecture we have already
examined, are solitary in their labours. Those we are about to describe
live in society. The perfection of the social state among this class of
insects is certainly that of the hive-bees. They are the inhabitants of
a large city, where the arts are carried to a higher excellence than
in small districts enjoying little communication of intelligence. But
the bees of the villages, if we may follow up the parallel, are not
without their interest. Such are those which are called carder-bees and
humble-bees.


Carder-Bees.

The nests of the bees which Reaumur denominates carders (_Bombus
muscorum_, Latr.) are by no means uncommon, and are well worth the
study of the naturalist. During the hay harvest, they are frequently
met with by mowers in the open fields and meadows; but they may
sometimes be discovered in hedge-banks, the borders of copses, or among
moss-grown stones. The description of the mode of building adopted
by this bee has been copied by most of our writers on insects from
Reaumur; though he is not a little severe on those who write without
having ever had a single nest in their possession. We have been able to
avoid such a reproach; for we have now before us a very complete nest
of carder-bees, which differs from those described by Reaumur, in being
made not of moss, but withered grass. With this exception, we find that
his account agrees accurately with our own observations. (J. R.)

[Illustration: Fig. A represents two Carder-Bees heckling moss for
their Nests; B, exterior view of the Nest of the Carder-Bee.]

The carder-bees select for their nest a shallow excavation about
half a foot in diameter; but when they cannot find one to suit their
purpose, they undertake the Herculean task of digging one themselves.
They cover this hollow with a dome of moss--sometimes, as we have
ascertained, of withered grass. They make use, indeed, of whatever
materials may be within their reach; for they do not attempt to bring
anything from a distance, not even when they are deprived of the
greater portion by an experimental naturalist. Their only method of
transporting materials to the building is by pushing them along the
ground--the bee, for that purpose, working backwards, with its head
turned from the nest. If there is only one bee engaged in this labour,
as usually happens in the early spring, when a nest is founded by a
solitary female who has outlived the winter, she transports her little
bundles of moss or grass by successive backward pushes, till she gets
them home.

In the latter part of the season, when the hive is populous and can
afford more hands, there is an ingenious division of this labour. A
file of bees, to the number sometimes of half a dozen, is established,
from the nest to the moss or grass which they intend to use, the heads
of all the file of bees being turned from the nest and towards the
material. The last bee of the file lays hold of some of the moss with
her mandibles, disentangles it from the rest, and having _carded_ it
with her fore legs into a sort of felt or small bundle, she pushes it
under her body to the next bee, who passes it in the same manner to the
next, and so on till it is brought to the border of the nest,--in the
same way as we sometimes see sugar-loaves conveyed from a cart to a
warehouse, by a file of porters throwing them from one to another.

The elevation of the dome, which is all built from the interior, is
from four to six inches above the level of the field. Beside the moss
or grass, they frequently employ coarse wax to form the ceiling of the
vault, for the purpose of keeping out rain, and preventing high winds
from destroying it. Before this finishing is given to the nest, we have
remarked, that on a fine sunshiny day the upper portion of the dome was
opened to the extent of more than an inch, in order, we suppose, to
forward the hatching of the eggs in the interior; but on the approach
of night this was carefully covered in again. It was remarkable that
the opening which we have just mentioned was never used by the bees for
either their entrance or their exit from the nest, though they were all
at work there, and, of course, would have found it the readiest and
easiest passage; but they invariably made their exit and their entrance
through the covert-way or gallery which opens at the bottom of the
nest, and, in some nests, is about a foot long and half an inch wide.
This is, no doubt, intended for concealment from field-mice, polecats,
wasps, and other depredators.

On removing a portion of the dome and bringing the interior of the
structure into view, we find little of the architectural regularity
so conspicuous in the combs of a common bee-hive: instead of this
symmetry, there are only a few egg-shaped, dark- cells, placed
somewhat irregularly, but approaching more to the horizontal than to
the vertical position, and connected together with small amorphous[T]
columns of brown wax. Sometimes there are two or three of these oval
cells placed one above another, without anything to unite them.

These cells are not, however, the workmanship of the old bees, but of
their young grubs, who spin them when they are about to change into
nymphs. But, from these cases, when they are spun, the enclosed insects
have no means of escaping, and they depend for their liberation on the
old bees gnawing off the covering, as is done also by ants in the same
circumstances. The instinct with which they know the precise time when
it is proper to do this is truly wonderful. It is no less so, that
these cocoons are by no means useless when thus untenanted, for they
subsequently serve for honey-pots, and are indeed the only store-cells
in the nest. For this purpose the edge of the cell is repaired and
strengthened with a ring of wax.

[Illustration: Breeding-Cells.]

The true breeding-cells are contained in several amorphous masses of
brown- wax, varying in dimensions, but of a somewhat flat and
globular shape. On opening any of these, a number of eggs or grubs are
found, on whose account the mother bee has collected the masses of
wax, which also contain a supply of pollen moistened with honey, for
their subsistence.

The number of eggs or grubs found in one spheroid of wax varies from
three to thirty, and the bees in a whole nest seldom exceed sixty.
There are three sizes of bees, of which the females are the largest;
but neither these nor the males are, as in the case of the hive-bee,
exempt from labour, the females, indeed, always found the nests, since
they alone survive the winter, all the rest perishing with cold. In
each nest, also, are several females, that live in harmony together.

[Illustration: Interior views of Carder-Bee's Nest.]

The carder-bees may be easily distinguished from their congeners (of
the same genus), by being not unlike the colour of the withered moss
with which they build their nests, having the fore part of their
back a dull orange, and hinder part ringed with different shades of
greyish yellow. They are not so large as the common humble-bee (_Bombus
terrestris_, Latr.), but rather shorter and thicker in the body than
the common hive-bee (_Apis mellifica_).


Lapidary-Bees.

A bee still more common, perhaps, than the carder is the orange-tailed
bee, or lapidary (_Bombus lapidaria_), readily known by its general
black colour and reddish orange tail. It builds its nest sometimes
in stony ground, but prefers a heap of stones such as are gathered
off grass fields or are piled up near quarries. Unlike the carder,
the lapidary carries to its nest bits of moss, which are very neatly
arranged into a regular oval. These insects associate in their labours;
and they make honey with great industry. The individuals of a nest
are more numerous than the carders, and likewise more pertinaciously
vindictive. About two years ago we discovered a nest of these bees at
Compton-Bassett, in Wiltshire, in the centre of a heap of limestone
rubbish; but owing to the brisk defensive warfare of their legionaries,
we could not obtain a view of the interior. It was not even safe to
approach within many yards of the place; and we do not exaggerate when
we say that several of them pursued us most pertinaciously about a
quarter of a mile. (J. R.)


Humble-Bees.

The common humble-bee (_Bombus terrestris_) is precisely similar in
its economy to the two preceding species, with this difference, that
it forms its nest underground like the common wasp, in an excavated
chamber, to which a winding passage leads, of from one to two feet, and
of a diameter sufficient to allow of two bees passing. The cells have
no covering beside the vault of the excavation and patches of coarse
wax similar to that of the carder-bee.

[The accompanying illustration represents a group of cells made by this
species. As may be seen by reference to the engraving, they are not
placed with any regularity, but seem to be tossed about at random.

[Illustration]

Some of the cells contain larvae, in others, those closely sealed, lie
the pupae in different stages of development, and some of the cells
are filled with a very fragrant and sweet honey, which, however, is
injurious to many persons, giving them severe and persistent headaches,
even though taken in small quantities.]


Social-Wasps.

The nest of the common wasp (_Vespa vulgaris_) attracts more or less
the attention of everybody; but its interior architecture is not so
well known as it deserves to be, for its singular ingenuity, in which
it rivals even that of the hive-bee (_Apis mellifica_). In their
general economy the social or republican wasps closely resemble the
humble-bee (_Bombus_), every colony being founded by a single female
who has survived the winter, to the rigours of which all her summer
associates of males and working wasps uniformly fall victims. Nay, out
of three hundred females which may be found in one vespiary, or wasp's
nest, towards the close of autumn, scarcely ten or a dozen survive till
the ensuing spring, at which season they awake from their hibernal
lethargy, and begin with ardour the labours of colonization.

It may be interesting to follow one of these mother wasps through her
several operations, in which she merits more the praise of industry
than the queen of a bee-hive, who does nothing, and never moves without
a numerous train of obedient retainers, always ready to execute her
commands and to do her homage. The mother wasp, on the contrary, is
at first alone, and is obliged to perform every species of drudgery
herself.

Her first care, after being roused to activity by the returning warmth
of the season, is to discover a place suitable for her intended colony;
and, accordingly, in the spring, wasps may be seen prying into every
hole of a hedge-bank, particularly where field-mice have burrowed.
Some authors report that she is partial to the forsaken galleries of
the mole; but this does not accord with our observations, as we have
never met with a single vespiary in any situation likely to have been
frequented by moles. But though we cannot assert the fact, we think it
highly probable that the deserted nest of the field-mouse, which is
not uncommon in hedge-banks, may be sometimes appropriated by a mother
wasp as an excavation convenient for her purpose. Yet, if she does make
choice of the burrow of a field-mouse, it requires to be afterwards
considerably enlarged in the interior chamber, and the entrance gallery
very much narrowed.

The desire of the wasp to save herself the labour of excavation, by
forming her nest where other animals have burrowed, is not without
a parallel in the actions of quadrupeds, and even of birds. In the
splendid continuation of Wilson's American Ornithology, by Charles L.
Bonaparte (whose scientific pursuits have thrown around that name
a beneficent lustre, pleasingly contrasted with his uncle's glory),
there is an interesting example of this instinctive adoption of the
labours of others. "In the trans-Mississippian territories of the
United States, the burrowing-owl resides exclusively in the villages
of the marmot, or prairie-dog, whose excavations are so commodious as
to render it unnecessary that the owl should dig for himself, as he is
said to do where no burrowing animals exist.[U] The villages of the
prairie-dog are very numerous and variable in their extent,--sometimes
covering only a few acres, and at others spreading over the surface of
the country for miles together. They are composed of slightly-elevated
mounds, having the form of a truncated cone, about two feet in width
at the base, and seldom rising as high as eighteen inches from the
surface of the soil. The entrance is placed either at the top or on
the side, and the whole mound is beaten down externally, especially
at the summit, resembling a much-used footpath. From the entrance,
the passage into the mound descends vertically for one or two feet,
and is thence continued obliquely downwards until it terminates in an
apartment, within which the industrious prairie-dog constructs, on the
approach of cold weather, a comfortable cell for his winter's sleep.
The cell, which is composed of fine dry grass, is globular in form,
with an opening at top, capable of admitting the finger; and the whole
is so firmly compacted, that it might without injury be rolled over the
floor."[V]

In case of need the wasp is abundantly furnished by nature with
instruments for excavating a burrow out of the solid ground, as she no
doubt most commonly does--digging the earth with her strong mandibles,
and carrying it off or pushing it out as she proceeds. The entrance
gallery is about an inch or less in diameter, and usually runs in a
winding or zig-zag direction, from one to two feet in depth. In the
chamber to which this gallery leads, and which, when completed, is from
one to two feet in diameter, the mother wasp lays the foundations of
her city, beginning with the walls.

The building materials employed by wasps were long a matter of
conjecture to scientific inquirers; for the bluish-grey papery
substance of the whole structure has no resemblance to any sort of wax
employed by bees for a similar purpose. Now that the discovery has
been made, we can with difficulty bring ourselves to believe that a
naturalist so acute and indefatigable as M. Reaumur, should have, for
twenty years, as he tells us, endeavoured, without success, to find
out the secret. At length, however, his perseverance was rewarded. He
remarked a female wasp alight on the sash of his window, and begin to
gnaw the wood with her mandibles; and it struck him at once that she
was procuring materials for building. He saw her detach from the wood a
bundle of fibres about a tenth of an inch in length, and finer than a
hair; and as she did not swallow these, but gathered them into a mass
with her feet, he could not doubt that his first idea was correct. In
a short time she shifted to another part of the window-frame, carrying
with her the fibres she had collected, and to which she continued to
add, when he caught her, in order to examine the nature of her bundle;
and he found that it was not yet moistened nor rolled into a ball, as
is always done before employing it in building. In every other respect
it had precisely the same colour and fibrous texture as the walls of a
vespiary. It struck him as remarkable that it bore no resemblance to
wood gnawed by other insects, such as the goat-moth caterpillar, which
is granular like sawdust. This would not have suited the design of the
wasp, who was well aware that fibres of some length form a stronger
texture. He even discovered, that before detaching the fibres, she
bruised them (_les charpissoit_) into a sort of lint (_charpie_) with
her mandibles. All this the careful naturalist imitated by bruising
and paring the same wood of the window-sash with his penknife, till
he succeeded in making a little bundle of fibres scarcely to be
distinguished from that collected by the wasp.

We have ourselves frequently seen wasps employed in procuring their
materials in this manner, and have always observed that they shift
from one part to another more than once in preparing a single load--a
circumstance which we ascribe entirely to the restless temper peculiar
to the whole order of hymenopterous insects. Reaumur found that
the wood which they preferred was such as had been long exposed to
the weather, and is old and dry. White of Selborne, and Kirby and
Spence, on the contrary, maintain that wasps obtain their paper from
sound timber, hornets only from that which is decayed.[W] Our own
observations, however, confirm the statement of Reaumur with respect
to wasps, as, in every instance which has fallen under our notice, the
wood selected was very much weathered; and in one case, an old oak post
in a garden at Lee, in Kent, half destroyed by dry-rot, was seemingly
the resort of all the wasps in the vicinity. In another case, the deal
bond in a brick wall, which had been built thirty years, is at this
moment (June, 1829) literally striped with the gnawings of wasps, which
we have watched at the work for hours together. (J. R.)

[Different species of wasps use different materials for their nest.
_Vespa vulgaris_ always uses decayed wood, while _V. germanica_ and
other species use sound wood. Owing to the colour, the distinction
between the nests of these insects is evident at a glance.

The bundles of ligneous fibres thus detached are moistened before being
used, with a glutinous liquid, which causes them to adhere together,
and are then kneaded into a sort of paste, or _papier mache_.

The method employed by the wasp in making its nest has been so
admirably described by Mr. S. Stone, that we cannot do better than copy
his description, which appeared in "Beeton's Annual" of 1865.

"Having found a place suitable--the deserted burrows of the field-mice
being perhaps more generally selected than any other by the underground
species, the chamber formed by that animal for its nest being exactly
the kind of place required by the insect--it proceeds to attach its web
to the centre of the roof of the chamber. This consists, in the first
instance, of a pedicle, or footstalk, about half an inch in length,
at the extremity of which a single cell is formed, which is presently
surrounded by others.

"Simultaneously with the formation of these cells, an umbrella-shaped
covering is prepared above them. More cells are added, an egg being
deposited in each of them as soon as formed, while constant additions
are made to the covering until it has assumed a globular form, with
only an aperture sufficiently large for the insect to pass in and out.
Before the completion of the first covering, a second, just large
enough to enclose it, is begun, and while this is in progress a third
is commenced, and then a fourth, and so on. When young wasps have
been produced in sufficient numbers to carry on the work without the
assistance of the parent, an event which usually takes place in about
six weeks from the commencement of the nest, she does not again leave
home, but occupies herself solely in the task of depositing eggs as
fast as cells can be formed by the workers for their reception.

"There are two methods by which the nests are enlarged by the workers
after the queen has given up the task of building; some species
choosing one, some adopting the other. One consists in forming a series
of regular sheets or layers, which are made to overlap each other like
the slates or tiles on the roof of a building, in the same way as is
pursued by the queen of every species so long as she continues to be
the architect. When a few of these sheets have been completed, that
is, when they have been made to assume a spherical form, with only a
small aperture for ingress and egress, each internal sheet is cut away,
nearly but not quite, as fast as additional ones are formed externally,
the shell or covering therefore slightly increasing in thickness as
the nest increases in size. Thus architects among the human race are
careful to proportion the thickness, and consequently the strength of
the walls to the magnitude of the building designed to be erected.

"The other method consists in forming hollow pieces, or raising, as it
were, blisters all over the plain surface which the queen has left;
and upon these other blisters, and so on continually; cutting away,
as in the former case, the under skin on the formation of the outer
one. The latter method is adopted by the workers of _V. crabro_, _V.
vulgaris_, and _V. germanica_; the former by _V. Norvegica_, _V.
sylvestris_, _V. rufa_, and probably by _V. arborea_. Cutting away the
inner portions of the coverings is a necessary process in order to make
room for the increased size of the comb or combs. The material cut away
is not thrown by as useless, but is worked up afresh; indeed this is
effected in, and by, the very act of removing it; it is then either
used in enlarging the combs or it is brought out and employed in making
additions to the outside.

"As the nest increases in size, it is obvious that the cavity in which
it is placed must be proportionably enlarged; accordingly, each wasp,
as it emerges from the aperture, may be observed to bring out with
it a small lump of earth which it has scraped from the walls of the
chamber, care being taken to keep a clear space of about a quarter of
an inch between the covering of the nest, and the walls of the chamber.
About the same space also occurs between the combs, which are placed
horizontally, with the mouth of the cells downwards; supporting columns
or pillars being constructed at regular intervals so as to keep them at
a proper distance apart, thus allowing the insects room to pass between
them for the purpose of feeding the grubs. Supporting columns or
pillars are also placed between the roof of the chamber and the crown
of the nest, connecting the one with the other; and these supports are
constantly strengthened as the increasing weight of the nest renders
such a precaution necessary.

"The material of which the wasps' nests are composed is a sort of
paper manufactured chiefly from wood by the insects themselves; one
species using sound wood for the purpose, another that which has become
decayed. This they scrape by means of their jaws from posts, rails,
gates, hurdles, &c., in which act it becomes mixed with some peculiar
fluid with which they are provided; it then possesses nearly the same
properties as the pulp from which paper is made, but is of firmer
consistence. This is gathered in a small lump under the chest, to which
it adheres, and in that way is carried to the nest.

"The operators having, after the exhibition of a considerable amount of
fickleness in the choice, fixed upon a suitable place for commencing,
or recommencing operations--for these remarks have reference to a nest
already somewhat advanced in the building--place themselves along the
edge of a yet unfinished piece, then walking slowly backward, spread
the material as they go, along this edge, where it forms a thick
streak; they then go forward to the point at which they began to spread
the composition, again marching slowly backward, press this streak
between their jaws, which acts as a pair of pincers, thus thinning it
out throughout its whole length. They then go forward a second time,
pressing it still thinner, and then a third, and so on, until they
have rendered it sufficiently thin. Before this is accomplished, the
operators have generally to go five or six times over their work. They
do not return to the same spot with their next burden, but seek a fresh
one, and thus allow the work they recently executed to become dry and
firm, previous to making further additions to it. Possibly the material
first 'used up' was from wood of a dark colour; the next may be from
light- wood, and the next from that of an intermediate colour;
and this it is which gives so much beauty to the coverings of the nests
of these insects.

"_Vespa crabro_ and _V. vulgaris_ are the only species which use
decayed wood or touchwood in the fabrication of their nests; the other
species employ sound wood, varied occasionally by sound vegetable fibre
obtained from plants of different kinds.

"From the upper combs in a nest, workers are produced; from the lower
ones, queens or females; and from the intermediate ones, males. Workers
become developed early in the season, males not till an advanced
period; and young females or queens not until towards the close of the
season.

"The nests of _V. crabro_, _V. vulgaris_, and _V. germanica_, when
of full size, measure not unfrequently twelve inches in diameter,
the communities working on, in a favourable season, until the month
of November; while the labours of the other species close, and the
communities break up towards the end of August; their nests scarcely
attaining to half the size of those above mentioned."

The accompanying illustration exhibits the nest of the common wasp in
an early stage. The first cover has been completed, and a second is in
course of progress. We have now before us a beautiful series of wasps'
nests, in their various stages, prepared by Mr. Stone, in order to show
the progressive enlargement of the edifice.

[Illustration: Nest of Wasp in an early stage.]

First, there is the single cell attached to a small part that had
penetrated the roof of the burrow. Next comes a more advanced stage, in
which three cells are made, and the roof is just begun, being not quite
half an inch in diameter. Then come five cells, and a tolerably large
roof; and then twelve cells, with a complete roof.

The next stage is that which is represented in the illustration, where
the group of cells is seen suspended from its slender footstalk, and
a second covering is in progress. By degrees the nest enlarges until
the second layer or tier of cells is begun, while the first tier is
occupied in the centre by the pupae, sheltered by their little silk
doors, and on the circumference by the larvae, whose cells are still
open in order to allow themselves to be fed by the nurse-wasps.

[Illustration: Section of the same Nest, showing the first tier of
Cells.]

In these nests, the difference between the homes of _Vespa vulgaris_
and those of _V. germanica_ is very strongly marked, the former being
yellowish brown, and the latter grey. One nest of _V. germanica_, is
remarkable for being thickly studded with the long, white eggs of some
insect, probably a parasite, which has gained admittance to the burrow,
in spite of the care of its guardians. It may be here mentioned, that
_V. germanica_ is by far the most common species of wasp in England.

The illustration at p. 90 represents a completed nest of _V.
germanica_. The rough, thick covering is seen outside, and within
are the tiers of cells, each layer being supported by pillars from
the layer immediately above. These pillars are always formed at the
angle where these cells touch each other, so as to obtain as strong a
foundation as possible. Only a very small space is left between the
combs, just enough room, in fact, for the nurse-wasps to pass as they
feed the young. The reader will remember that the young wasps all hang
with their heads downwards, being held in their places by a sort of
clasper at the end of the tail.]

When the foundress-wasp has completed a certain number of cells, and
deposited eggs in them, she soon intermits her building operations,
in order to procure food for the young grubs, which now require all
her care. In a few weeks these become perfect wasps, and lend their
assistance in the extension of the edifice; enlarging the original
coping of the foundress by side walls, and forming another platform of
cells, suspended to the first by columns, as that had been suspended to
the ceiling.

[Illustration: Section of the Social-Wasp's Nest.

_a a_, the external wall; _b_, _c c_, five small terraces of cells for
the neuter wasps, _d d_, _e e_, three rows of larger cells for the
males and females.]

In this manner several platforms of combs are constructed, the outer
walls being extended at the same time; and, by the end of the summer,
there is generally from twelve to fifteen platforms of cells. Each
contains about 1060 cells--forty-nine being contained in an inch and a
half square, and, of course, making the enormous number of about 16,000
cells in one colony. Reaumur, upon these data, calculates that one
vespiary may produce every year more than 30,000 wasps, reckoning only
10,000 cells, and each serving successively for the cradle of three
generations. But, although the whole structure is built at the expense
of so much labour and ingenuity, it has scarcely been finished before
the winter sets in, when it becomes nearly useless, and serves only for
the abode of a few benumbed females, who abandon it on the approach of
spring, and never return; for wasps do not, like mason-bees, ever make
use of the same nest for more than one season.

[Illustration: A, represents one of the rods from which the terraces
are suspended. B, a portion of the external crust.]

Both Reaumur and the younger Huber studied the proceedings of the
common wasp in the manner which has been so successful in observing
bees--by means of glazed hives, and other contrivances. In this, these
naturalists were greatly aided by the extreme affection of wasps for
their young; for though their nest is carried off, or even cut in
various directions, and exposed to the light, they never desert it, nor
relax their attention to their progeny. When a wasp's nest is removed
from its natural situation, and covered with a glass hive, the first
operation of the inhabitants is to repair the injuries it has suffered.
They carry off with surprising activity all the earth or other matters
which have fallen by accident into the nest; and when they have got it
thoroughly cleared of everything extraneous, they begin to secure it
from further derangement, by fixing it to the glass with papyraceous
columns, similar to those which we have already described. The
breaches which the nest may have suffered are then repaired, and the
thickness of the walls is augmented, with the design, perhaps, of more
effectually excluding the light.

       *       *       *       *       *

The nest of the hornet is nearly the same in structure with that of
the wasp; but the materials are considerably coarser, and the columns
to which the platforms of cells are suspended are larger and stronger,
the middle one being twice as thick as any of the others. The hornet,
also, does not build underground, but in the cavities of trees, or in
the thatch or under the eaves of barns. Reaumur once found upon a wall
a hornet's nest which had not been long begun, and had it transferred
to the outside of his study-window; but in consequence, as he imagined,
of the absence of the foundress-hornet at the time it was removed, he
could not get the other five hornets, of which the colony consisted,
either to add to the building or repair the damages which it had
sustained.

[Illustration: Hornet's Nest in its first stage.]

M. Reaumur differs from our English naturalists, White, and Kirby
and Spence, with respect to the materials employed by the hornet for
building. The latter say that it employs decayed wood; the former, that
it uses the bark of the ash-tree, but takes less pains to split it
into fine fibres than wasps do; not, however, because it is destitute
of skill; for in constructing the suspensory columns of the platforms,
a paste is prepared little inferior to that made by wasps. We cannot,
from our own observations, decide which of the above statements is
correct, as we have only once seen a hornet procuring materials, at
Compton-Bassett, in Wiltshire; and in that case it gnawed the inner
bark of an elm which had been felled for several months, and was,
consequently, dry and tough. Such materials as this would account for
the common yellowish-brown colour of a hornet's nest. (J. R.)

[Illustration]

[The accompanying figure represents a completed hornet's nest as it
appears when suspended from a beam. Hornets often choose for their
home the space between the roof and the ceiling of summer-houses,
and the nests that are made in such localities are mostly large and
handsome. The reader should notice the blisters by means of which the
insect enlarges its habitation.]

When hornets make choice of a tree for their domicile, they select one
which is in a state of decay, and already partly hollowed; but they
possess the means, in their sharp and strong mandibles, of extending
the excavation to suit their purposes; and Reaumur frequently witnessed
their operations in mining into a decayed tree, and carrying off what
they had gnawed. He observed, also, that in such cases they did not
make use of the large hole of the tree for an entrance, but went to
the trouble of digging a gallery, sufficient for the passage of the
largest hornet in the nest, through the living and undecayed portion of
the tree. As this is perforated in a winding direction, it is no doubt
intended for the purpose of protecting the nest from the intrusion of
depredators, who could more easily effect an entrance if there were not
such a tortuous way to pass through.

[Illustration: Hornet's Nest in a hollow tree.]

[Here is an illustration of a hornet's nest as it appears in the hollow
of a tree. Industrious as is this insect, it never takes needless
trouble, and alters its nest according to circumstances. As has already
been seen, the combs are defended by a complete cover when the nest is
placed in an open situation. But when it is built in the hollow of a
tree there is no cover at all, the insect evidently knowing that the
wooden wall with which the cells are surrounded, affords a sufficient
protection. In cases where a cover is made, the hornets do not form
only a single entrance, as is the case with the wasp, but have a large
number of small entrances in different parts of the wall. Some of these
entrances can be seen in the illustration on page 93.

Hornets are in one sense more industrious than wasps. When night falls,
the wasps betake themselves to their home, and sleep throughout the
night. But, if the moon be up, the hornet is sure to work throughout
the entire night, and will often do so, even when no moon is visible.]

       *       *       *       *       *

One of the most remarkable of our native social wasps is the tree-wasp
(_Vespa Britannica_), which is not uncommon in the northern, but is
seldom to be met with in the southern parts of the island. Instead of
burrowing in the ground like the common wasp (_Vespa vulgaris_), or
in the hollows of trees like the hornet (_Vespa crabro_), it boldly
swings its nest from the extremity of a branch, where it exhibits
some resemblance, in size and colour, to a Welsh wig hung out to
dry. We have seen more than one of these nests on the same tree, at
Catrine, in Ayrshire, and at Wemyss Bay, in Renfrewshire. The tree
which the Britannic wasp prefers is the silver fir, whose broad flat
branch serves as a protection to the suspended nest both from the
sun and the rain. We have also known a wasp's nest of this kind in a
gooseberry-bush, at Red-house Castle, East Lothian. The materials and
structure are nearly the same as those employed by the common wasp, and
which we have already described. (J. R.)

[We have before us a beautiful example of a nest made by this species
of wasp. There are no less than three consecutive coverings quite
entire, while another is about three-fourths completed, and a fifth is
just begun. The illustration exhibits a very perfect specimen.]

[Illustration]

A singular nest of a species of wasp is figured by Reaumur, but is
apparently rare in this country, as Kirby and Spence mention only a
single nest of similar construction, found in a garden at East-Dale.
This nest is of a flattened globular figure, and composed of a great
number of envelopes, so as to assume a considerable resemblance to a
half-expanded Provence rose. The British specimen mentioned by Kirby
and Spence had only one platform of cells; Reaumur had two; but there
was a large vacant space, which would probably have been filled with
cells, had the nest not been taken away as a specimen. The whole nest
was not much larger than a rose, and was composed of paper exactly
similar to that employed by the common ground-wasp.[X]

[This is probably the nest of _V. rufa_. We possess several specimens
of the nest, one of which corresponds tolerably closely with the
edifice described in the work.]

[Illustration: Wasp's Nest.]

There is another species of social-wasp (_Epipone nidulans_, Latr.)
meriting attention from the singular construction of its nest. It forms
one or more terraces of cells, similar to those of the common wasp,
but without the protection of an outer wall, and quite exposed to the
weather. Swammerdam found a nest of this description attached to the
stem of a nettle. Reaumur says that they are sometimes attached to the
branch of a thorn or other shrub, or to stalks of grass;--peculiarities
which prove that there are several species of these wasps.

[Illustration: Wasps' Cells attached to a Branch.]

The most remarkable circumstance in the architecture of this species
of vespiary is, that it is not horizontal, like those formerly
described, but nearly vertical. The reason appears to be, that if it
had been horizontal, the cells must have been frequently filled with
rain; whereas, in the position in which it is placed, the rain runs
off without lodging. It is, besides, invariably placed so as to face
the north or the east, and consequently is less exposed to rains,
which most frequently come with southerly or westerly winds. It is
another remarkable peculiarity, that, unlike the nests of other wasps,
it is covered with a shining coat of varnish, to prevent moisture
from soaking into the texture of the wasp's paper. The laying on
this varnish, indeed, forms a considerable portion of the labour of
the colony, and individuals may be seen employed for hours together
spreading it on with their tongues.

[Illustration: Comb of Polistes.]

[There is a genus of foreign hymenoptera, called _Polistes_, which
is remarkable for the building powers possessed by its members. The
accompanying illustration is taken from a nest in the British Museum,
and is given of the natural size. The cells are not hexagonal, like
those of the _Epipone_, but are roundish in form. Those in the centre
assume a roughly hexagonal form by pressure, but those which form the
circumference of the cell-group are nearly round, especially on their
outer sides. The cells are not of uniform width, but are narrower at
the base than at the mouth, thus causing the group to assume the form
which is seen in the illustration. This curious group of cells was
brought from Bareilly, in the East Indies, and in the same collection
there are several other specimens, varying considerably both in shape
and size.]

Few circumstances are more striking, with regard to insects, as Kirby
and Spence justly remark, than the great and incessant labour which
maternal affection for their progeny leads them to undergo. Some of
these exertions are so disproportionate to the size of the insect,
that nothing short of ocular conviction could attribute them to such
an agent. A wild bee, or a wasp, for instance, as we have seen, will
dig a hole in a hard bank of earth some inches deep, and five or six
times its own size, labouring unremittingly at this arduous task for
several days in succession, and scarcely allowing itself a moment for
eating or repose. It will then occupy as much time in searching for a
store of food; and no sooner is this finished, than it will set about
repeating the process, and, before it dies, will have completed five or
six similar cells, or even more.

We shall have occasion more particularly to dwell upon the geometrical
arrangement of the cells, both of the wasp and of the social-bee,
in our description of those interesting operations, which have long
attracted the notice, and commanded the admiration of mathematicians
and naturalists. A few observations may here be properly bestowed upon
the _material_ with which the wasp-family construct the interior of
their nests.

The wasp is a paper-maker, and a most perfect and intelligent one.
While mankind were arriving, by slow degrees, at the art of fabricating
this valuable substance, the wasp was making it before their eyes, by
very much the same process as that by which human hands now manufacture
it with the best aid of chemistry and machinery. While some nations
carved their records on wood, and stone, and brass, and leaden
tablets,--others, more advanced, wrote with a style on wax,--others
employed the inner bark of trees, and others the skins of animals
rudely prepared,--the wasp was manufacturing a firm and durable paper.
Even when the papyrus was rendered more fit, by a process of art, for
the transmission of ideas in writing, the wasp was a better artisan
than the Egyptians; for the early attempts at paper-making were so
rude, that the substance produced was almost useless, from being
extremely friable. The paper of the papyrus was formed of the leaves
of the plant, dried, pressed, and polished; the wasp alone knew how
to reduce vegetable fibres to a pulp, and then unite them by a size
or glue, spreading the substance out into a smooth and delicate leaf.
This is exactly the process of paper-making. It would seem that the
wasp knows, as the modern paper-makers now know, that the fibres of
rags, whether linen or cotton, are not the only materials that can be
used in the formation of paper; she employs other vegetable matters,
converting them into a proper consistency by her assiduous exertions.
In some respects she is more skilful even than our paper-makers, for
she takes care to retain her fibres of sufficient length, by which she
renders her paper as strong as she requires. Many manufacturers of
the present day cut their material into small bits, and thus produce
a rotten article. One great distinction between good and bad paper is
its toughness; and this difference is invariably produced by the fibre
of which it is composed being long, and therefore tough; or short, and
therefore friable.

The wasp has been labouring at her manufacture of paper from her first
creation, with precisely the same instruments and the same materials;
and her success has been unvarying. Her machinery is very simple,
and therefore it is never out of order. She learns nothing, and she
forgets nothing. Men, from time to time, lose their excellence in
particular arts, and they are slow in finding out real improvements.
Such improvements are often the effect of accident. Paper is now
manufactured very extensively by machinery in all its stages; and
thus, instead of a single sheet being made by hand, a stream of
paper is poured out, which would form a roll large enough to extend
round the globe, if such a length were desirable. The inventors of
this machinery, Messrs. Fourdrinier, it is said, spent the enormous
sum of 40,000_l._. in vain attempts to render the machine capable
of determining with precision the width of the roll; and, at last,
accomplished their object, at the suggestion of a bystander, by
a strap revolving upon an axis, at a cost of three shillings and
sixpence. Such is the difference between the workings of human
knowledge and experience, and those of animal instinct. We proceed
slowly and in the dark, but our course is not bounded by a narrow
line, for it seems difficult to say what is the perfection of any art;
animals go clearly to a given point--but they can go no further. We
may, however, learn something from their perfect knowledge of what is
within their range. It is not improbable that if man had attended in an
earlier state of society to the labours of wasps, he would have sooner
known how to make paper. We are still behind in our arts and sciences,
because we have not always been observers. If we had watched the
operations of insects, and the structure of insects in general, with
more care, we might have been far advanced in the knowledge of many
arts which are yet in their infancy, for nature has given us abundance
of patterns. We have learnt to perfect some instruments of sound by
examining the structure of the human ear; and the mechanism of an eye
has suggested some valuable improvements in achromatic glasses.

Reaumur has given a very interesting account of the wasps of Cayenne
(_Chartergus nidulans_), which hang their nests in trees.[Y] Like
the bird of Africa called the social grosbeak (_Loxia socia_), they
fabricate a perfect house, capable of containing many hundreds of
their community, and suspend it on high out of the reach of attack.
But the Cayenne wasp is a more expert artist than the bird. He is
a pasteboard-maker;--and the card with which he forms the exterior
covering of his abode is so smooth, so strong, so uniform in its
texture, and so white, that the most skilful manufacturer of this
substance might be proud of the work. It takes ink admirably.

The nest of the pasteboard-making wasp is impervious to water. It hangs
upon the branch of a tree, as represented in the engraving; and those
rain-drops which penetrate through the leaves never rest upon its hard
and polished surface. A small opening for the entrance of the insects
terminates its funnel-shaped bottom. It is impossible to unite more
perfectly the qualities of lightness and strength.

[Illustration: Nest of the Pasteboard-maker Wasp, with part removed to
show the arrangement of the Cells.]

In the specimen from which we take our description, the length of
which is nine inches, six stout circular platforms stretch internally
across, like so many floors, and fixed all round to the walls of the
nest. They are smooth above, with hexagonal cells on the under surface.
These platforms are not quite flat, but rather concave above, like a
watch-glass reversed; the centre of each platform is perforated for
the admission of the wasps, at the extremity of a short funnel-like
projection, and through this access is gained from story to story. On
each platform, therefore, can the wasps walk leisurely about attending
to the pupae secured in the cells, which, with the mouths downward,
cover the ceiling above their heads--the height of the latter being
just convenient for their work.

[Unlike the habitations made by the British wasps, and which are
vacated annually, this nest is permanent, and serves for several
successive seasons. Of course, it must be enlarged continually, so
as to accommodate an ever-increasing number of inhabitants. The mode
of enlarging is sufficiently curious. The British wasps enlarge
their nests either by making a larger covering and then removing the
smaller, or by raising blisters on the outside, and eating away beneath
them. But the pendulous wasp of Brazil proceeds on just the opposite
principle, making new cells first, and covering them afterwards. The
new tier of cells is set on the bottom of the nest, which thus becomes
the floor of that tier, and a new bottom is then made beneath these new
cells.]

Pendent wasps' nests of enormous size are found in Ceylon, suspended
often in the talipot-tree at the height of seventy feet. The appearance
of these nests thus elevated, with the larger leaves of the tree,
used by the natives as umbrellas and tents, waving over them, is very
singular. Though no species of European wasp is a storer of honey,
yet this rule does not apply to certain species of South America. In
the 'Annals and Magazine of Natural History' for June, 1841, will be
found a detailed account, with a figure, of the pendent nest of a
species termed by Mr. A. White _Myrapetra scutellaris_. The external
case consists of stout cardboard covered with conical knobs of various
sizes. The entrances are artfully protected by pent-roofs from the
weather and heavy rains; and are tortuous, so as to render the ingress
of a moth or other large insect difficult. Internally are fourteen
combs, exclusive of a globular mass, the nucleus of several circular
combs, which are succeeded by others of an arched form--that is,
constituting segments of circles. Many of the uppermost combs were
found to have the cells filled with honey of a brownish-red colour, but
which had lost its flavour. After entering into some minute details,
Mr. A. White makes the following interesting observations:--"Azara,
in the account of his residence in various parts of South America,
mentions the fact of _several wasps_ of these countries collecting
honey. The Baron Walchenaer, who edited the French translation of
this work, published in 1809, thought that the Spanish traveller, who
was unskilled in entomology, had made some mistake with regard to
the insects, and regarded the so-called _wasps_ as belonging to some
_bee_ of the genus of which _Apis amalthea_ is the type (_Melipona_).
Latreille (who afterwards corrected his mistake) also believed that
they must be referred to the genera _Melipona_ or _Trigona_--insects
which in South America take the place of our honey-bee. These authors
were afterwards clearly convinced of the correctness of Azara's
observations, by the circumstance of M. Auguste de St. Hilaire finding
near the river Uruguay an oval grey- nest of a papery
consistence, like that of the European wasps, suspended from the
branches of a small shrub about a foot from the ground: he and two
other attendants partook of some honey (contained in its cells) and
found it of an agreeable sweetness, free from the pharmaceutic taste
which so frequently accompanies European honey. He gives a detailed
account of its poisonous effects on himself and his two men. Afterwards
he procured specimens of the wasp, which was described by Latreille
under the name of _Polistes Lecheguana_."

[Illustration: Nest of Myrapetra.]

[The accompanying illustration shows this remarkable nest, both as it
appears externally, and when divided vertically.

The material is probably the dung of the Capincha, an animal allied
to the guinea-pig and the agouti. The natives, at all events, state
that such is the case, and the aspect of the nest as seen through a
magnifying glass carries out this assertion. The nest is hung to a
branch, and is seldom more than four feet from the ground. The insect
is a very little one in comparison with the size of the nest, which is
sixteen inches in length, and twelve in width. The largest specimens of
this insect are only one third of an inch long, while the generality
scarcely exceed a quarter of an inch. Its colour is brown.

In the section is shown the very peculiar shape of the combs. At the
upper part is seen the globular centre, surrounded with a comb that
completely encircles it. Other combs follow in order, but are less
curved as they approach the bottom of the nest. The insects obtain
admission to the several tiers by means of apertures which are left
between the extremities of the comb and the wall of the nest. The combs
are made of the same material as the outer wall, but are very thin and
paper-like. This nest may be seen in the British Museum.]

It would seem that the nest described by Mr. White agrees with that
of a wasp termed _Chiguana_ by Azara (or _Lecheguana_), and is very
different to the slight papery nest of the _Polistes Lecheguana_ of
Latreille. We may add that M. Auguste de St. Hilaire speaks of two
species of wasps remarkable for storing honey in South America; the
honey of one is white, of the other reddish. That the habits of these
honey-wasps must differ considerably from those of any of our European
species we may at once admit; perhaps in some points of their economy
these insects may approach the bee.

[In the same country as is inhabited by the _Myrapetra_, and in
much the same localities, is sometimes found the nest of another
honey-making wasp, called _Nectarinia analis_, a small and plainly-clad
insect. It is hung to the branches of low trees and underwood, and
often includes both twigs and leaves in its structure. The combs of
this insect are greatly curved, in order to suit the shape of the
general covering, but are not arranged with that beautiful regularity
which distinguishes those of the _Myrapetra_. A specimen of this nest
may be seen in the British Museum, and as the outer covering has been
partially taken away, the observer will be enabled to note the general
form of the combs and the structure of the cells.

In the accompanying illustration are shown the habitations of two
remarkable insects, both belonging to the _Hymenoptera_. Indeed, the
greater number of pensile nests made by insects are formed by members
of this important order; and, if we were to exclude all the wasps,
bees, and ants, we should find that we had excluded about ninety per
cent. of the pensile architects.

The left-hand figure represents a nest made by a species of _Polybia_,
inhabiting Brazil. It is made of a papery kind of substance, of rather
slight texture, and is fixed to the stalk of a reed. The outside of the
nest is seen to be marked with a series of horizontal ribs. These show
the progressive stages of the nest, each rib marking a layer of paper
as it was spread by the insect builder. The combs extend throughout the
entire nest, the largest occupying the centre, and the smallest the
ends. Each comb is firmly supported by a footstalk, which is fixed, not
to the upper tier of cells, as is the case with the British wasps, but
to the reed on which the nest is built.

Other species of _Polybia_ build nests different in shape and
arrangement, though still of the pensile character. One species builds
a nearly globular nest, made in a rather curious manner. Carrying out
still farther the principle on which the cardboard wasp enlarges its
nest, the _Polybia_ entirely covers the outer wall with cells, and
then makes a new wall over them. When a nest has reached a tolerable
size, it is composed of a whole series of concentric combs, the roof of
each having been originally the outer wall of the nest. There are in
the British Museum some admirable specimens of these nests, in some of
which the process of enlargement can be very clearly traced. Patches of
new cells are seen upon the external covering, while a few breaches in
the structure show the concentric combs.

[Illustration: Nests of Polybia.]

One very curious point about these cells is, that they are not uniform
in their direction, as is generally the case with those of social
hymenoptera. The greater part, such as the various wasps, hornets, and
their kin, have the mouths of the cells downwards, while the cells of
the hive-bee are nearly horizontal. But the cells of this insect are
arranged without the least regard to their position, all the bases
pointing towards the centre of the nest, and all the mouths radiating
outwards.

[Illustration: Nests of Synaeca and Polybia.]

There seems to be scarcely any bound to the variety which exists in the
nests of the social hymenoptera. The insect which makes the nest which
is represented in the illustration is a native of Brazil, and is known
to entomologists as _Synaeca cyanea_. The first of these names is given
to it on account of its social habits, and the second, in reference to
the bluish colour of its body. It is rather larger than the preceding
insects, being about three quarters of an inch in length. Its wings are
brown.

The shape and size of the nest are exceedingly variable, but it is
almost invariably longer than wide, and is fixed to a branch or some
similar object. Sometimes it attains considerable dimensions, and has
been known to measure a full yard in length. Yet, however large it may
be, there is only a single comb, which is set upon the side of the nest
next the branch, and, in consequence, has almost all its cells placed
in a horizontal direction. In the illustration, the right-hand figure
represents the external appearance of the nest, and the central figure
shows the manner in which the single comb is set upon the branch. The
nest which occupies the left hand of the illustration is made by a
species of _Polybia_, and is here given in order to show a remarkable
example of similarity in the mode of building adopted by two different
insects. In the one case, however, the cells are all fastened by their
bases to the branch, but in the other the cells are attached to one
common base which is prolonged into a footstalk.

There have been lately discovered some very remarkable social nests.
Specimens of both these nests may be seen in the entomological
department of the museum at Oxford.

The first is formed very much like a rather flattened Florence flask,
and is hung by the neck from the branch of a tree. It is made of a
strong, parchment-like substance, formed by innumerable silken threads
woven and matted together into a kind of felt. When it was cut open a
most singular sight was exhibited. Nearly the whole of the interior
was covered with the pupae of some butterfly, all hanging by their
tails, and many of them suspended to a twig which projected downwards
into the nest. Although the nest is barely eight inches in length, a
great proportion of which is taken up by the neck, about one hundred
pupae were found in it. At the bottom of the nest is a small and nearly
circular aperture, through which the insects could make their way as
soon as they escaped from the pupal envelope, and before their wings
became extended and hardened.

The butterfly which makes this singular nest is a native of Mexico, and
is named _Eucheira socialis_. The colour of its wings is dark brown,
with an ill-defined white band across them.

The second nest was brought from tropical Africa, and is remarkable
for another peculiarity. It is shaped much like a cushion, and its
measurements are, eight inches in length, five and a half in breadth,
and three in depth. Instead of having only one place of exit for the
inmates, it has thirteen or fourteen, all formed in the same manner. A
number of short, stiff, and almost bristly threads are set round the
apertures, their ends all projecting outwards, and converging to a
point, where they all meet and even slightly cross each other. Owing to
this structure, it is easy enough for any of the insects to pass out,
as the converging hairs yield to the pressure, whereas they form an
effectual barrier against any insect that wishes to creep into the nest.

The material of the nest is very strong and hard, and is formed of two
layers, the inner being made of smooth brown silk, and the outer of
harsher and stronger orange silk threads.]




_CHAPTER V._

ARCHITECTURE OF THE HIVE-BEE.


[Illustration: Part of a Honeycomb, and Bees at work.]

Although the hive-bee (_Apis mellifica_) has engaged the attention
of the curious from the earliest ages, recent discoveries prove that
we are yet only beginning to arrive at a correct knowledge of its
wonderful proceedings. Pliny informs us that Astromachus, of Soles, in
Cilicia, devoted fifty-eight years to the study; and that Philiscus the
Thracian spent his whole life in forests for the purpose of observing
them. But in consequence (as we may naturally infer) of the imperfect
methods of research, assuming that what they did discover was known to
Aristotle, Columella, and Pliny, we are justified in pronouncing the
statements of these philosophers, as well as the embellished poetical
pictures of Virgil, to be nothing more than conjecture, almost in every
particular erroneous. It was not indeed till 1711, when glass hives
were invented by Maraldi, a mathematician of Nico, that what we may
call the in-door proceedings of bees could be observed. This important
invention was soon afterwards taken advantage of by M. Reaumur, who
laid the foundation of the more recent discoveries of John Hunter,
Schirach, and the Hubers. The admirable architecture which bees
exhibit in their miniature cities has, by these and other naturalists,
been investigated with great care and accuracy. We shall endeavour
to give as full an account of the wonderful structures as our limits
will allow. In this we shall chiefly follow M. Huber the elder, whose
researches appear almost miraculous when we consider that he was blind.

At the early age of seventeen this remarkable man lost his sight by
_gutta serena_, the "drop serene" of our own Milton. But though cut off
from the sight of Nature's works, he dedicated himself to their study.
He saw them through the eyes of the admirable woman whom he married;
his philosophical reasonings pointed out to her all that he wanted to
ascertain; and as she reported to him from time to time the results
of his ingenious experiments, he was enabled to complete, by diligent
investigation, one of the most accurate and satisfactory accounts of
the habits of bees which had ever been produced.

It had long been known that the bees of a hive consist of three sorts,
which was ascertained by M. Reaumur to be distinguished as workers or
neuters, constituting the bulk of the population; drones or males, the
least numerous class; and a single female, the queen and mother of
the colony. Schirach subsequently discovered the very extraordinary
fact, which Huber and others have proved beyond doubt, that when a
hive is accidentally deprived of a queen, the grub of a worker can be
and is fed in a particular manner so as to become a queen and supply
the loss.[Z] But another discovery of M. Huber is of more importance
to the subject of architecture now before us. By minute research he
ascertained that the workers which had been considered by former
naturalists to be all alike, are divided into two important classes,
nurse-bees and wax-makers.

The _nurse-bees_ are rather smaller than the wax-workers, and even
when gorged with honey their belly does not, as in the others, appear
distended. Their business is to collect honey, and impart it to their
companions; to feed and take care of the young grubs, and to complete
the combs and cells which have been founded by the others; but they are
not charged with provisioning the hive.

The _wax-workers_, on the other hand, are not only a little larger,
but their stomach, when gorged with honey, is capable of considerable
distension, as M. Huber proved by repeated experiments. He also
ascertained that neither of the varieties can alone fulfil all the
functions shared among the workers of a hive. He painted those of each
class with different colours, in order to study their proceedings,
and their labours were not interchanged. In another experiment, after
supplying a hive deprived of a queen with brood and pollen, he saw the
nurse-bees quickly occupied in the nutrition of the grubs, while those
of the wax-working class neglected them. When hives are full of combs,
the wax-workers disgorge their honey into the ordinary magazines,
making no wax; but if they want a reservoir for its reception, and if
their queen does not find cells ready made wherein to lay her eggs,
they retain the honey in the stomach, and in twenty-four hours they
produce wax. Then the labour of constructing combs begins.

It might perhaps be supposed that, when the country does not afford
honey, the wax-workers consume the provision stored up in the hive. But
they are not permitted to touch it. A portion of honey is carefully
preserved, and the cells containing it are protected by a waxen
covering, which is never removed except in case of extreme necessity,
and when honey is not to be otherwise procured. The cells are at
no time opened during summer; other reservoirs, always exposed,
contribute to the daily use of the community; each bee, however,
supplying itself from them with nothing but what is required for
present wants. Wax-workers appear with large bellies at the entrance of
their hive only when the country affords a copious collection of honey.
From this it may be concluded that the production of the waxy matter
depends on a concurrence of circumstances not invariably subsisting.
Nurse-bees also produce wax, but in a very inferior quantity to what
is elaborated by the real wax-workers. Another characteristic whereby
an attentive observer can determine the moment of bees collecting
sufficient honey to produce wax, is the strong odour of both these
substances from the hive, which is not equally intense at any other
time. From such data, it was easy for M. Huber to discover whether
the bees worked in wax in his own hives, and in those of the other
cultivators of the district.

There is still another sort of bee, first observed by Huber in 1809,
which appear to be only casual inmates of the hive, and which are
driven forth to starve, or are killed in conflict. They closely
resemble the ordinary workers, but are less hairy, and of a much darker
colour. These have been called _black bees_, and are supposed by Huber
to be defective bees;[AA] but Kirby and Spence conjecture that they are
toil-worn superannuated workers, of no further use, and are therefore
sacrificed, because burdensome to a community which tolerates no
unnecessary inmates.


Preparation of Wax.

In order to build the beautiful combs, which every one must
have repeatedly seen and admired, it is indispensable that the
architect-bees should be provided with the materials--with the wax,
in short, of which they are principally formed. Before we follow
them, therefore, to the operation of building, it may be necessary
to inquire how the wax itself is procured. Here the discoveries of
recent inquirers have been little less singular and unexpected than
in other departments of the history of these extraordinary insects.
Now that it has been proved that wax is secreted by bees, it is not a
little amusing to read the accounts given by our elder naturalists, of
its being collected from flowers. Our countryman, Thorley,[AB] appears
to have been the first who suspected the true origin of wax, and
Wildman (1769) seems also to have been aware of it; but Reaumur, and
particularly Bonnet, though both of them in general shrewd and accurate
observers, were partially deceived by appearances.

The bees, we are erroneously told, search for wax "upon all sorts of
trees and plants, but especially the rocket, the simple poppy, and
in general all kinds of flowers. They amass it with their hair, with
which their whole body is invested. It is something pleasant to see
them roll in the yellow dust which falls from the chives to the bottom
of the flowers, and then return covered with the same grains; but
their best method of gathering the wax, especially when it is not very
plentiful, is to carry away all the little particles of it with their
jaws and fore feet, to press the wax upon them into little pellets,
and slide them one at a time, with their middle feet, into a socket or
cavity, that opens at their hinder feet, and serves to keep the burthen
fixed and steady till they return home. They are sometimes exposed to
inconveniences in this work by the motion of the air, and the delicate
texture of the flowers, which bend under their feet and hinder them
from packing up their booty, on which occasions they fix themselves in
some steady place, where they press the wax into a mass, and wind it
round their legs, making frequent returns to the flowers; and when they
have stocked themselves with a sufficient quantity, they immediately
repair to their habitation. Two men, in the compass of a whole day,
could not amass so much as two little balls of wax; and yet they are no
more than the common burthen of a single bee, and the produce of one
journey. Those who are employed in collecting the wax from flowers
are assisted by their companions, who attend them at the door of the
hive, ease them of their load at their arrival, brush their feet, and
shake out the two balls of wax; upon which the others return to the
fields to gather new treasure, while those who disburthened them convey
their charge to the magazine. But some bees, again, when they have
brought their load home, carry it themselves to the lodge, and there
deliver it, laying hold of one end by their hinder feet, and with their
middle feet sliding it out of the cavity that contained it; but this
is evidently a work of supererogation which they are not obliged to
perform. The packets of wax continue a few moments in the lodge, till
a set of officers come, who are charged with a third commission, which
is to knead this wax with their feet, and spread it out into different
sheets, laid one above another. This is the unwrought wax, which is
easily distinguished to be the produce of different flowers, by the
variety of colours that appear on each sheet. When they afterwards
come to work, they knead it over again; they purify and whiten, and
then reduce it to a uniform colour. They use this wax with a wonderful
frugality; for it is easy to observe that the whole family is conducted
by prudence, and all their actions regulated by good government.
Everything is granted to necessity, but nothing to superfluity; not
the least grain of wax is neglected, and if they waste it, they are
frequently obliged to provide more; at those very times when they want
to get their provision of honey, they take off the wax that closed the
cells, and carry it to the magazine."[AC]

Reaumur hesitated in believing that this was a correct view of the
subject, from observing the great difference between wax and pollen;
but he was inclined to think the pollen might be swallowed, partially
digested, and disgorged in the form of a kind of paste. Schirach also
mentions, that it was remarked by a certain Lusatian, that wax comes
from the rings of the body, because, on withdrawing a bee while it is
at work, and extending its body, the wax may be seen there in the form
of scales.

The celebrated John Hunter shrewdly remarked that the pellets of pollen
seen on the thighs of bees are of different colours on different bees,
while the shade of the new-made comb is always uniform; and therefore
he concluded that pollen was not the origin of wax. Pollen also, he
observed, is collected with greater avidity for old hives, where the
comb is complete, than for those where it is only begun, which would
hardly be the case were it the material of wax. He found that when the
weather was cold and wet in June, so that a young swarm was prevented
from going abroad, as much comb was constructed as had been made in an
equal time when the weather was favourable and fine.

The pellets of pollen on the thighs being thence proved not to be
wax, he came to the conclusion that it was an external secretion,
originating between the plates of the belly. When he first observed
this, he felt not a little embarrassed to explain the phenomenon, and
doubted whether new plates were forming, or whether bees cast their old
ones as lobsters do their shell. By melting the scales, he ascertained
at least that they were wax; and his opinion was confirmed by the fact,
that the scales are only to be found during the season when the combs
are constructed. But he did not succeed in completing the discovery by
observing the bees actually detach the scales, though he conjectured
they might be taken up by others, if they were once shaken out from
between the rings.[AD]

We need not be so much surprised at mistakes committed upon this
subject, when we recollect that honey itself was believed by the
ancients to be an emanation of the air--a dew that descended upon
flowers, as if it had a limited commission to fall only on them. The
exposure and correction of error is one of the first steps to genuine
knowledge; and when we are aware of the stumbling-blocks which have
interrupted the progress of others, we can always travel more securely
in the way of truth.

That wax is secreted is proved both by the wax-pouches within the
rings of the abdomen, and by actual experiment. Huber and others fed
bees entirely upon honey or sugar, and, notwithstanding, wax was
produced and combs formed as if they had been at liberty to select
their food. "When bees were confined," says M. Huber, "for the purpose
of discovering whether honey was sufficient for the production of
wax, they supported their captivity patiently, and showed uncommon
perseverance in rebuilding their combs as we removed them. Our
experiments required the presence of grubs; honey and water had to be
provided; the bees were to be supplied with combs containing brood, and
at the same time it was necessary to confine them, that they might not
seek pollen abroad. Having a swarm by chance, which had become useless
from sterility of the queen, we devoted it for our investigation in one
of my leaf-hives, which was glazed on both sides. We removed the queen,
and substituted combs containing eggs and young grubs, but no cell with
farina; even the smallest particle of the substance which John Hunter
conjectured to be the basis of the nutriment of the young was taken
away.

"Nothing remarkable occurred during the first and second day: the bees
brooded over the young, and seemed to take an interest in them; but at
sunset on the third a loud noise was heard in the hive. Impatient to
discover the reason, we opened a shutter, and saw all in confusion;
the brood was abandoned, the workers ran in disorder over the combs,
thousands rushed towards the lower part of the hive, and those about
the entrance gnawed at its grating. Their design was not equivocal;
they wished to quit their prison. Some imperious necessity evidently
obliged them to seek elsewhere what they could not find in the hive;
and apprehensive that they might perish if I restrained them longer
from yielding to their instinct, I set them at liberty. The whole
swarm escaped, but the hour being unfavourable for their collections,
they flew around the hive, and did not depart far from it. Increasing
darkness and the coolness of the air compelled them very soon to
return. Probably these circumstances calmed their agitation; for
we observed them peaceably remounting their combs; order seemed
re-established, and we took advantage of this moment to close the hive.

"Next day, the 19th of July, we saw the rudiments of two royal cells,
which the bees had formed on one of the brood-combs. This evening, at
the same hour as on the preceding, we again heard a loud buzzing in
the closed hive; agitation and disorder rose to the highest degree,
and we were again obliged to let the swarm escape. The bees did not
remain long absent from their habitation; they quieted and returned
as before. We remarked on the 20th that the royal cells had not been
continued, as would have been the case in the ordinary state of
things. A great tumult took place in the evening; the bees appeared to
be in a delirium; we set them at liberty, and order was restored on
their return. Their captivity having endured five days, we thought it
needless to protract it farther; besides, we were desirous of knowing
whether the brood was in a suitable condition, and if it had made the
usual progress; and we wished also to try to discover what might be
the cause of the periodical agitation of the bees. M. Burnens (the
assistant of Huber), having exposed the two brood-combs, the royal
cells were immediately recognised; but it was obvious that they had
not been enlarged. Why should they? Neither eggs, grubs, nor that kind
of paste peculiar to the individuals of their species were there! The
other cells were vacant likewise; no brood, not an atom of paste, was
in them. Thus, the worms had died of hunger. Had we precluded the bees
from all means of sustenance by removing the farina? To decide this
point, it was necessary to confide other brood to the care of the
same insects, now giving them abundance of pollen. They had not been
enabled to make any collections while we examined their combs. On this
occasion they escaped in an apartment where the windows were shut; and
after substituting young worms for those they had allowed to perish,
we returned them to their prison. Next day we remarked that they had
resumed courage; they had consolidated the combs, and remained on the
brood. They were then provided with fragments of combs, where other
workers had stored up farina; and to be able to observe what they did
with it, we took this substance from some of their cells, and spread
it on the board of the hive. The bees soon discovered both the farina
in the combs and what we had exposed to them. They crowded to the
cells, and also descending to the bottom of the hives, took the pollen
grain by grain in their teeth, and conveyed it to their mouths. Those
that had eaten it most greedily mounted the combs before the rest,
and stopping on the cells of the young worms, inserted their heads,
and remained there for a certain time. M. Burnens opened one of the
divisions of the hive gently, and powdered the workers, for the purpose
of recognising them when they should ascend the combs. He observed them
during several hours, and by this means ascertained that they took
so great a quantity of pollen only to impart it to their young. Then
withdrawing the portions of comb which had been placed by us on the
board of the hive, we saw that the pollen had been sensibly diminished
in quantity. They were returned to the bees, to augment their provision
still further, for the purpose of extending the experiment. The royal,
as well as several common, cells were soon closed; and, on opening the
hive, all the worms were found to have prospered. Some still had their
food before them; the cells of others that had spun were shut with a
waxen covering.

"We witnessed these facts repeatedly, and always with equal interest.
They so decisively prove the regard of the bees towards the grubs which
they are intrusted with rearing, that we shall not seek for any other
explanation of their conduct. Another fact, no less extraordinary,
and much more difficult to be accounted for, was exhibited by bees
constrained to work in wax, several times successively, from the syrup
of sugar. Towards the close of the experiment they ceased to feed the
young, though in the beginning these had received the usual attention.
They even frequently dragged them from their cells, and carried them
out of the hive."[AE]

Mr. Wiston, of Germantown, in the United States, mentions a fact
conclusive on this subject. "I had," says he, "a late swarm last
summer, which, in consequence of the drought, filled only one box with
honey. As it was late in the season, and the food collected would not
enable the bees to subsist for the winter, I shut up the hive, and gave
them half-a-pint of honey every day. They immediately set to work,
filled the empty cells, and then constructed new cells enough to fill
another box, in which they deposited the remainder of the honey."

A more interesting proof is thus related by the same gentleman: "In the
summer of 1824, I traced some wild bees, which had been feeding on the
flowers in my meadow, to their home in the woods, and which I found in
the body of an oak-tree, exactly fifty feet above the ground. Having
caused the entrance to the hive to be closed by an expert climber,
the limbs were separated in detail, until the trunk alone was left
standing. To the upper extremity of this, a tackle-fall was attached so
as to connect it with an adjacent tree, and, a saw being applied below,
the naked trunk was cut through. When the immense weight was lowered
nearly to the earth, the ropes broke, and the mass fell with a violent
crash. The part of the tree which contained the hive, separated by the
saw, was conveyed to my garden, and placed in a vertical position. On
being released, the bees issued out by thousands, and though alarmed,
soon became reconciled to the change of situation. By removing a part
of the top of the block the interior of the hive was exposed to view,
and the comb itself, nearly six feet in height, was observed to have
fallen down two feet below the roof of the cavity. To repair the
damage was the first object of the labourers: in doing which, a large
part of their store of honey was expended, because it was at too late
a season to obtain materials from abroad. In the following February
these industrious but unfortunate insects issuing in a confused manner
from the hive, fell dead in thousands around its entrance, the victims
of a poverty created by their efforts to repair the ruins of their
habitation."[AF]

In another experiment, M. Huber confined a swarm so that they had
access to nothing beside honey, and five times successively removed the
combs with the precaution of preventing the escape of the bees from
the apartment. On each occasion they produced new combs, which puts it
beyond dispute that honey is sufficient to effect the secretion of wax
without the aid of pollen. Instead of supplying the bees with honey,
they were subsequently fed, exclusively, on pollen and fruit; but
though they were kept in captivity for eight days under a bell-glass,
with a comb containing nothing but farina, they neither made wax nor
was any secreted under the rings. In another series of experiments, in
which bees were fed with different sorts of sugar, it was found that
nearly one-sixth of the sugar was converted into wax, dark-
sugar yielding more than double the quantity of refined sugar.

It may not be out of place to subjoin the few anatomical and
physiological facts which have been ascertained by Huber, Maddle,
Jurine, and Latreille.

[Illustration: Worker-bee, magnified--showing the position of the
scales of Wax.]

The first stomach of the worker-bee, according to Latreille,[AG] is
appropriated to the reception of honey, but this is never found in the
second stomach, which is surrounded with muscular rings, and from one
end to the other very much resembles a cask covered with hoops. It is
within these rings that the wax is produced; but the secreting vessels
for this purpose have hitherto escaped the researches of the acutest
naturalists. Huber, however, plausibly enough conjectures that they are
contained in the internal lining of the wax-pockets, which consists
of a cellular substance reticulated with hexagons. The wax-pockets
themselves, which are concealed by the overlapping of the rings, may
be seen by pressing the abdomen of a worker-bee so as to lengthen it,
and separate the rings further from each other. When this has been
done, there may be seen on each of the four intermediate hoops of
the belly, and separated by what may be called the keel (_carina_),
two whitish- pouches, of a soft texture, and in the form of
a trapezium. Within, the little plates or scales of wax are produced
from time to time, and are removed and employed as we shall presently
see. We may remark, that it is chiefly the wax-workers which produce
the wax; for though the nurse-bees are furnished with wax-pockets, they
secrete it only in very small quantities; while in the queen-bee, and
the males or drones, no pockets are discoverable.

[Illustration: Abdomen of Wax-worker Bee.]

"All the scales," says Huber, "are not alike in every bee, for a
difference is perceptible in consistence, shape, and thickness; some
are so thin and transparent as to require a magnifier to be recognised,
or we have been able to discover nothing but spiculae similar to those
of water freezing. Neither the spiculae nor the scales rest immediately
on the membrane of the pocket, a slight liquid medium is interposed,
serving to lubricate the joinings of the rings, or to render the
extraction of the scales easier, as otherwise they might adhere too
firmly to the sides of the pockets." M. Huber has seen the scales so
large as to project beyond the rings, being visible without stretching
the segments, and of a whitish yellow, from greater thickness lessening
their transparency. These shades of difference in the scales of various
bees, their enlarged dimensions, the fluid interposed beneath them, the
correspondence between the scale and the size and form of the pockets,
seem to infer the oozing of this substance through the membranes
whereon it is moulded. He was confirmed in this opinion by the escape
of a transparent fluid on piercing the membrane, whose internal surface
seemed to be applied to the soft parts of the belly. This he found
coagulated in cooling, when it resembled wax, and again liquefied on
exposure to heat. The scales themselves, also, melted and coagulated
like wax.[AH]

By chemical analysis, however, it appears that the wax of the rings
is a more simple substance than that which composes the cells; for
the latter is soluble in ether, and in spirit of turpentine, while
the former is insoluble in ether, and but partially soluble in spirit
of turpentine. It should seem to follow, that if the substance found
lying under the rings be really the elements of wax, it undergoes
some subsequent preparation after it is detached; and that the bees,
in short, are capable of impregnating it with matter, imparting to it
whiteness and ductility, whereas in its unprepared state it is only
fusible.


Propolis.

Wax is not the only material employed by bees in their architecture.
Beside this, they make use of a brown, odoriferous, resinous substance,
called _propolis_,[AI] more tenacious and extensible than wax, and
well adapted for cementing and varnishing. It was strongly suspected
by Reaumur that the bees collected the propolis from those trees which
are known to produce a similar gummy resin, such as the poplar, the
birch, and the willow; but he was thrown into doubt by not being able
to detect the bees in the act of procuring it, and by observing them
to collect it where none of those trees, nor any other of the same
description, grew. His bees also refused to make use of bitumen, and
other resinous substances, with which he supplied them, though Mr.
Knight, as we shall afterwards see, was more successful.[AJ]

Long before the time of Reaumur, however, Mouffet, in his _Insectarum
Theatrum_, quotes Cordus for the opinion that propolis is collected
from the buds of trees, such as the poplar and birch; and Reim says
it is collected from the pine and fir.[AK] Huber at length set
the question at rest; and his experiments and observations are so
interesting, that we shall give them in his own words:--

"For many years," says he, "I had fruitlessly endeavoured to find them
on trees producing an analogous substance, though multitudes had been
seen returning laden with it.

"In July, some branches of the wild poplar, which had been cut since
spring, with very large buds, full of a reddish, viscous, odoriferous
matter, were brought to me, and I planted them in vessels before hives,
in the way of the bees going out to forage, so that they could not be
insensible of their presence. Within a quarter of an hour, they were
visited by a bee, which separating the sheath of a bud with its teeth,
drew out threads of the viscous substance, and lodged a pellet of it
in one of the baskets of its limbs; from another bud it collected
another pellet for the opposite limb, and departed to the hive. A
second bee took the place of the former in a few minutes, following
the same procedure. Young shoots of poplar, recently cut, did not seem
to attract these insects, as their viscous matter had less consistence
than the former.[AL]

"Different experiments proved the identity of this substance with the
propolis; and now, having only to discover how the bees applied it to
use, we peopled a hive, so prepared as to fulfil our views. The bees,
building upwards, soon reached the glass above; but, unable to quit
their habitation, on account of rain, they were three weeks without
bringing home propolis. Their combs remained perfectly white until
the beginning of July, when the state of the atmosphere became more
favourable for our observations. Serene, warm weather engaged them to
forage, and they returned from the fields laden with a resinous gum,
resembling a transparent jelly, and having the colour and lustre of
the garnet. It was easily distinguished from the farinaceous pellets
then collected by other bees. The workers bearing the propolis ran over
the clusters, suspended from the roof of the hive, and rested on the
rods supporting the combs, or sometimes stopped on the sides of their
dwelling, in expectation of their companions coming to disencumber them
of their burthen. We actually saw two or three arrive, and carry the
propolis from off the limbs of each with their teeth. The upper part
of the hive exhibited the most animated spectacle; thither a multitude
of bees resorted from all quarters, to engage in the predominant
occupation of the collection, distribution, and application of the
propolis. Some conveyed that of which they had unloaded the purveyors
in their teeth, and deposited it in heaps; others hastened, before its
hardening, to spread it out like a varnish, or formed it into strings,
proportioned to the interstices of the sides of the hives to be filled
up. Nothing could be more diversified than the operations carried on.

"The bees, apparently charged with applying the propolis within the
cells, were easily distinguished from the multitude of workers, by the
direction of their heads towards the horizontal pane forming the roof
of the hive, and on reaching it, they deposited their burthen nearly
in the middle of intervals separating the combs: then they conveyed
the propolis to the real place of its destination. They suspended
themselves by the claws of the hind legs to points of support, afforded
by the viscosity of the propolis on the glass; and, as it were,
swinging themselves backwards and forwards, brought the heap of this
substance nearer to the cells at each impulse. Here the bees employed
their fore feet, which remained free, to sweep what the teeth had
detached, and to unite the fragments scattered over the glass, which
recovered all its transparency when the whole propolis was brought to
the vicinity of the cells.

"After some of the bees had smoothed down and cleaned out the glazed
cells, feeling the way with their antennae, one desisted, and having
approached a heap of propolis, drew out a thread with its teeth. This
being broken off, it was taken in the claws of the fore feet, and the
bee, re-entering the cell, immediately placed it in the angle of two
portions that had been smoothed, in which operation the fore feet and
teeth were used alternately; but probably proving too clumsy, the
thread was reduced and polished; and we admired the accuracy with which
it was adjusted when the work was completed. The insect did not stop
here: returning to the cell, it prepared other parts of it to receive
a second thread, for which we did not doubt that the heap would be
resorted to. Contrary to our expectation, however, it availed itself
of the portion of the thread cut off on the former occasion, arranged
it in the appointed place, and gave it all the solidity and finish
of which it was susceptible. Other bees completed the work which the
first had begun: and the sides of the cells were speedily secured with
threads of propolis, while some were also put on the orifices; but we
could not seize the moment when they were varnished, though it may be
easily conceived how it is done."[AM]

This is not the only use to which bees apply the propolis. They are
extremely solicitous to remove such insects or foreign bodies as happen
to get admission into the hive. When so light as not to exceed their
powers, they first kill the insect with their stings, and then drag it
out with their teeth. But it sometimes happens, as was first observed
by Maraldi, and since by Reaumur and others, that an ill-fated slug
creeps into the hive: this is no sooner perceived than it is attacked
on all sides, and stung to death. But how are the bees to carry out
so heavy a burthen? Such a labour would be in vain. To prevent the
noxious smell which would arise from its putrefaction, they immediately
embalm it, by covering every part of its body with propolis, through
which no effluvia can escape. When a snail with a shell gets entrance,
to dispose of it gives much less trouble and expense to the bees. As
soon as it receives the first wound from a sting, it naturally retires
within its shell. In this case, the bees, instead of pasting it all
over with propolis, content themselves with gluing all round the
margin of the shell, which is sufficient to render the animal for ever
immovably fixed.

Mr. Knight, the learned and ingenious President of the Horticultural
Society, discovered by accident an artificial substance, more
attractive than any of the resins experimentally tried by Reaumur.
Having caused the decorticated part of a tree to be covered with a
cement composed of bees'-wax and turpentine, he observed that this was
frequented by hive-bees, who, finding it to be a very good propolis
ready made, detached it from the tree with their mandibles, and then,
as usual, passed it from the first leg to the second, and so on. When
one bee had thus collected its load, another often came behind and
despoiled it of all it had collected; a second and a third load were
frequently lost in the same manner; and yet the patient insect pursued
its operations without manifesting any signs of anger.[AN] Probably
the latter circumstance, at which Mr. Knight seems to have been
surprised, was nothing more than an instance of the division of labour
so strikingly exemplified in every part of the economy of bees.

[Illustration: Structure of the legs of the Bee, for carrying propolis
and pollen, magnified.]

It may not be out of place here to describe the apparatus with which
the worker-bees are provided for the purpose of carrying the propolis
as well as the pollen of flowers to the hive, and which has just been
alluded to in the observations of Mr. Knight. The shin or middle
portion of the hind pair of legs is actually formed into a triangular
basket, admirably adapted to this design. The bottom of this basket is
composed of a smooth, shining, horn-like substance, hollowed out in
the substance of the limb, and surrounded with a margin of strong and
thickly-set bristles. Whatever materials, therefore, may be placed by
the bee in the interior of this basket, are secured from falling out by
the bristles around it, whose elasticity will even allow the load to be
heaped beyond their points without letting it fall.

In the case of propolis, when the bee is loading her singular basket,
she first kneads the piece she has detached with her mandibles, till it
becomes somewhat dry and less adhesive, as otherwise it would stick to
her limbs. This preliminary process sometimes occupies nearly half an
hour. She then passes it backwards by means of her feet to the cavity
of her basket, giving it two or three pats to make it adhere; and when
she adds a second portion to the first, she often finds it necessary to
pat it still harder. When she has procured as much as the basket will
conveniently hold, she flies off with it to the hive.


The Building of the Cells.

The notion commonly entertained respecting glass hives is altogether
erroneous. Those who are unacquainted with bees, imagine that, by
means of a glass hive, all their proceedings may be easily watched and
recorded; but it is to be remembered that bees are exceedingly averse
to the intrusion of light, and their first operation in such cases
is to close up every chink by which light can enter to disturb them,
either by clustering together, or by a plaster composed of propolis.
It consequently requires considerable management and ingenuity, even
with the aid of a glass hive, to see them actually at work. M. Huber
employed a hive with leaves, which opened in the manner of a book; and
for some purposes he used a glass box, inserted in the body of the
hive, but easily brought into view by means of screws.

But no invention hitherto contrived is sufficient to obviate every
difficulty. The bees are so eager to afford mutual assistance, and
for this purpose so many of them crowd together in rapid succession,
that the operations of individuals can seldom be traced. Though this
crowding, however, appears to an observer to be not a little confused,
it is all regulated with admirable order, as has been ascertained by
Reaumur and other distinguished naturalists.

When bees begin to build the hive, they divide themselves into bands,
one of which produces materials for the structure; another works
upon these, and forms them into a rough sketch of the dimensions and
partitions of the cells. All this is completed by the second band, who
examine and adjust the angles, remove the superfluous wax, and give
the work its necessary perfection; and a third band brings provisions
to the labourers, who cannot leave their work. But no distribution of
food is made to those whose charge, in collecting propolis and pollen,
calls them to the field, because it is supposed they will hardly forget
themselves; neither is any allowance made to those who begin the
architecture of the cells. Their province is very troublesome, because
they are obliged to level and extend, as well as cut and adjust the
wax to the dimensions required; but then they soon obtain a dismission
from this labour, and retire to the fields to regale themselves with
food, and wear off their fatigue with a more agreeable employment.
Those who succeed them, draw their mouth, their feet, and the extremity
of their body, several times over all the work, and never desist till
the whole is polished and completed; and as they frequently need
refreshments, and yet are not permitted to retire, there are waiters
always attending, who serve them with provisions when they require
them. The labourer who has an appetite, bends down his trunk before the
caterer to intimate that he has an inclination to eat, upon which the
other opens his bag of honey, and pours out a few drops: these may be
distinctly seen rolling through the hole of his trunk, which insensibly
swells in every part the liquor flows through. When this little repast
is over, the labourer returns to his work, and his body and feet repeat
the same motions as before.[AO]

Before they can commence building, however, when a colony or swarm
migrates from the original hive to a new situation, it is necessary
first to collect propolis, with which every chink and cranny in the
place where they mean to build may be carefully stopped up; and
secondly, that a quantity of wax be secreted by the wax-workers to
form the requisite cells. The secretion of wax, it would appear, goes
on best when the bees are in a state of repose; and the wax-workers,
accordingly, suspend themselves in the interior in an extended cluster,
like the curtain which is composed of a series of intertwined festoons
or garlands, crossing each other in all directions--the uppermost bee
maintaining its position by laying hold of the roof with its fore legs,
and the succeeding one by laying hold of the hind legs of the first.

[Illustration: Curtain of Wax-workers secreting wax.]

"A person," says Reaumur, "must have been born devoid of curiosity not
to take interest in the investigation of such wonderful proceedings."
Yet Reaumur himself seems not to have understood that the bees
suspended themselves in this manner to secrete wax, but merely, as he
imagined, to recruit themselves by rest for renewing their labours.
The bees composing the festooned curtain are individually motionless;
but this curtain is, notwithstanding, kept moving by the proceedings
in the interior; for the nurse-bees never form any portion of it,
and continue their activity--a distinction with which Reaumur was
unacquainted.

Although there are many thousand labourers in a hive, they do not
commence foundations for combs in several places at once, but wait
till an individual bee has selected a site, and laid the foundation of
a comb, which serves as a directing mark for all that are to follow.
Were we not expressly told by so accurate an observer as Huber, we
might hesitate to believe that bees, though united in what appears
to be an harmonious monarchy, are strangers to subordination, and
subject to no discipline. Hence it is, that though many bees work on
the same comb, they do not appear to be guided by any simultaneous
impulse. The stimulus which moves them is successive. An individual
bee commences each operation, and several others successively apply
themselves to accomplish the same purpose. Each bee appears, therefore,
to act individually, either as directed by the bees preceding it,
or by the state of advancement in which it finds the work it has to
proceed with. If there be anything like unanimous consent, it is the
inaction of several thousand workers while a single individual proceeds
to determine and lay down the foundation of the first comb. Reaumur
regrets that, though he could by snatches detect a bee at work in
founding cells or perfecting their structure, his observations were
generally interrupted by the crowding of other bees between him and
the little builder. He was therefore compelled rather to infer the
different steps of their procedure from an examination of the cells
when completed, than from actual observation. The ingenuity of Huber,
even under all the disadvantages of blindness, succeeded in tracing the
minutest operations of the workers from the first waxen plate of the
foundation. We think the narrative of the discoverer's experiments,
as given by himself, will be more interesting than any abstract of it
which we could furnish:--

"Having taken a large bell-shaped glass receiver, we glued thin wooden
slips to the arch at certain intervals, because the glass itself was
too smooth to admit of the bees supporting themselves on it. A swarm,
consisting of some thousand workers, several hundred males, and a
fertile queen, was introduced, and they soon ascended to the top.
Those first gaining the slips fixed themselves there by the fore-feet;
others, scrambling up the sides, joined them, by holding their legs
with their own, and they thus formed a kind of chain, fastened by the
two ends to the upper parts of the receiver, and served as ladders or a
bridge to the workers enlarging their number. The latter were united in
a cluster, hanging like an inverted pyramid from the top to the bottom
of the hive.

"The country then affording little honey, we provided the bees with
syrup of sugar, in order to hasten their labour. They crowded to the
edge of a vessel containing it; and, having satisfied themselves,
returned to the group. We were now struck with the absolute repose of
this hive, contrasted with the usual agitation of bees. Meanwhile,
the nurse-bees alone went to forage in the country; they returned
with pollen, kept guard at the entrance of the hive, cleansed it, and
stopped up its edges with propolis. The wax-workers remained motionless
about fifteen hours: the curtain of bees, consisting always of the same
individuals, assured us that none replaced them. Some hours later, we
remarked that almost all these individuals had wax scales under the
rings; and next day this phenomenon was still more general. The bees
forming the external layer of the cluster, having now somewhat altered
their position, enabled us to see their bellies distinctly. By the
projection of the wax scales, the rings seemed edged with white. The
curtain of bees became rent in several places, and some commotion began
to be observed in the hive.

"Convinced that the combs would originate in the centre of the swarm,
our whole attention was then directed towards the roof of the glass. A
worker at this time detached itself from one of the central festoons
of the cluster, separated itself from the crowd, and, with its head,
drove away the bees at the beginning of the row in the middle of the
arch, turning round to form a space an inch or more in diameter, in
which it might move freely. It then fixed itself in the centre of the
space thus cleared.

[Illustration: Wax-worker laying the foundation of the first Cell.]

"The worker now employing the pincers at the joint of one of the third
pair of its limbs, seized a scale of wax projecting from a ring, and
brought it forward to its mouth with the claws of its fore-legs, where
it appeared in a vertical position. We remarked that, with its claws,
it turned the wax in every necessary direction; that the edge of the
scale was immediately broken down, and the fragments having been
accumulated in the hollow of the mandibles, issued forth like a very
narrow ribbon, impregnated with a frothy liquid by the tongue. The
tongue itself assumed the most varied shapes, and executed the most
complicated operations,--being sometimes flattened like a trowel, and
at other times pointed like a pencil; and, after imbuing the whole
substance of the ribbon, pushed it forward again into the mandibles,
whence it was drawn out a second time, but in an opposite direction.

[Illustration: Curtain of Wax-workers (see p. 132).]

"At length the bee applied these particles of wax to the vault of the
hive, where the saliva impregnating them promoted their adhesion, and
also communicated a whiteness and opacity which were wanting when the
scales were detached from the rings. Doubtless this process was to give
the wax that ductility and tenacity belonging to its perfect state.
The bee then separated those portions not yet applied to use with
its mandibles, and with the same organs afterwards arranged them at
pleasure. The founder bee, a name appropriated to this worker, repeated
the same operation, until all the fragments, worked up and impregnated
with the fluid, were attached to the vault, when it repeated the
preceding operations on the part of the scale yet kept apart, and
again united to the rest what was obtained from it. A second and third
scale were similarly treated by the same bee; yet the work was only
sketched; for the worker did nothing but accumulate the particles of
wax together. Meanwhile the founder, quitting its position, disappeared
amidst its companions. Another, with wax under the rings, succeeded
it, which suspending itself to the same spot, withdrew a scale by
the pincers of the hind legs, and passing it through its mandibles,
prosecuted the work; and taking care to make its deposit in a line with
the former, it united their extremities. A third worker, detaching
itself from the interior of the cluster, now came and reduced some of
the scales to paste, and put them near the materials accumulated by
its companions, but not in a straight line. Another bee, apparently
sensible of the defect, removed the misplaced wax before our eyes, and
carrying it to the former heap, deposited it there, exactly in the
order and direction pointed out.

"From all these operations was produced a block of a rugged surface,
hanging down from the arch, without any perceptible angle, or any
traces of cells. It was a simple wall, or ridge, running in a straight
line, and without the least inflection, two-thirds of an inch in
length, above two-thirds of a cell, or two lines, high, and declining
towards the extremities. We have seen other foundation walls from an
inch to an inch and a half long, the form being always the same; but
none ever of greater height.

"The vacuity in the centre of the cluster had permitted us to discover
the first manoeuvres of the bees, and the art with which they laid the
foundations of their edifices. However, it was filled up too soon for
our satisfaction; for workers collecting on both faces of the wall
obstructed our view of their further operations."[AP]




_CHAPTER VI._

ARCHITECTURE OF THE HIVE-BEE CONTINUED--FORM OF THE CELLS.


The obstruction of which M. Huber complains only operated as a
stimulus to his ingenuity in contriving how he might continue his
interesting observations. From the time of Pappus to the present
day, mathematicians have applied the principles of geometry to
explain the construction of the cells of a bee-hive; but though their
extraordinary regularity, and wonderfully-selected form, had so often
been investigated by men of the greatest talent, and skilled in all
the refinements of science, the process by which they are constructed,
involving also the causes of their regularity of form, had not been
traced till M. Huber devoted himself to the inquiry.

As the wax-workers secrete only a limited quantity of wax, it is
indispensably requisite that as little as possible of it should be
consumed, and that none of it should be wasted. Bees, therefore, as
M. Reaumur well remarks,[AQ] have to solve this difficult geometrical
problem:--a quantity of wax being given, to form of it similar and
equal cells of a determinate capacity, but of the largest size in
proportion to the quantity of matter employed, and disposed in such
a manner as to occupy the least possible space in the hive. This
problem is solved by bees in all its conditions. The cylindrical form
would seem to be best adapted to the shape of the insect; but had
the cells been cylindrical, they could not have been applied to each
other without leaving a vacant and superfluous space between every
three contiguous cells. Had the cells, on the other hand, been square
or triangular, they might have been constructed without unnecessary
vacancies; but these forms would have both required more material, and
have been very unsuitable to the shape of a bee's body. The six-sided
form of the cells obviates every objection; and while it fulfils the
conditions of the problem, it is equally adapted with a cylinder to the
shape of the bee.

M. Reaumur further remarks, that the base of each cell, instead of
forming a plane, is usually composed of three pieces in the shape of
the diamonds on playing cards, and placed in such a manner as to form a
hollow pyramid. This structure, it may be observed, imparts a greater
degree of strength, and, still keeping the solution of the problem
in view, gives a great capacity with the smallest expenditure of
material. This has actually, indeed, been ascertained by mathematical
measurement and calculation. Maraldi, the inventor of glass hives,
determined, by minutely measuring these angles, that the greater were
109 deg. 28', and the smaller 70 deg. 32'; and M. Reaumur, being desirous to
know why these particular angles are selected, requested M. Koenig, a
skilful mathematician (without informing him of his design, or telling
him of Maraldi's researches), to determine by calculation what ought
to be the angle of a six-sided cell, with a concave pyramidal base,
formed of three similar and equal rhomboid plates, so that the least
possible matter should enter into its construction. By employing what
geometricians denominate the _infinitesimal calculus_, M. Koenig found
that the angles should be 109 deg. 26' for the greater, and 70 deg. 34' for
the smaller, or about two-sixtieths of a degree, more or less, than
the actual angles made choice of by bees. The equality of inclination
in the angles has also been said to facilitate the construction of the
cells.

M. Huber adds to these remarks, that the cells of the first row, by
which the whole comb is attached to the roof of a hive, are not like
the rest; for, instead of six sides, they have only five, of which
the roof forms one. The base, also, is in these different, consisting
of three pieces on the face of the comb, and on the other side of
two: one of these only is diamond-shaped, while the other two are of
an irregular four-sided figure. This arrangement, by bringing the
greatest number of points in contact with the interior surface, insures
the stability of the comb.

[Illustration: Arrangement of Cells.]

It may, however, be said not to be quite certain, that Reaumur and
others have not ascribed to bees the merit of ingenious mathematical
contrivance and selection, when the construction of the cells may
more probably originate in the form of their mandibles and the other
instruments employed in their operations. In the case of other insects,
we have, both in the preceding and subsequent pages of this volume,
repeatedly noticed, that they use their bodies, or parts thereof, as
the standards of measurement and modelling; and it is not impossible
that bees may proceed on a similar principle. M. Huber replies to this
objection, that bees are not provided with instruments corresponding
to the angles of their cells; for there is no more resemblance between
these and the form of their mandibles, than between the chisel of the
sculptor and the work which he produces. The head, he thinks, does not
furnish any better explanation. He admits that the antennae are very
flexible, so as to enable the insects to follow the outline of every
object; but concludes that neither their structure, nor that of the
limbs and mandibles, are adequate to explain the form of the cells,
though all these are employed in the operations of building,--the
effect, according to him, depending entirely on the object which the
insect proposes.

We shall now follow M. Huber in the experiments which he contrived, in
order to observe the operations of the bees subsequent to their laying
a foundation for the first cell; and we shall again quote from his own
narrative:--

"It appeared to me," he says, "that the only method of isolating
the architects, and bringing them individually into view, would be
to induce them to change the direction of their operations and work
upwards.

"I had a box made twelve inches square and nine deep, with a moveable
glass lid. Combs, full of brood, honey, and pollen, were next selected
from one of my leaf-hives, as containing what might interest the bees,
and being cut into pieces a foot long, and four inches deep, they were
arranged vertically at the bottom of the box, at the same intervals
as the insects themselves usually leave between them. A small slip
of wooden lath covered the upper edge of each. It was not probable
that the bees would attempt to found new combs on the glass roof of
the box, because its smoothness precluded the swarm from adhering
to it; therefore, if disposed to build, they could do so over the
slips resting on the combs, which left a vacuity five inches high
above them. As we had foreseen, the swarm with which this box was
peopled established itself among the combs below. We then observed the
nurse-bees displaying their natural activity. They dispersed themselves
throughout the hive, to feed the young grubs, to clear out their
lodgment, and adapt it for their convenience. Certainly, the combs,
which were roughly cut to fit the bottom of the box, and in some parts
damaged, appeared to them shapeless and misplaced; for they speedily
commenced their reparation. They beat down the old wax, kneaded it
between their teeth, and thus formed binding materials to consolidate
them. We were astonished beyond expression by such a multitude of
workers employed at once in labours to which it did not appear they
should have been called, at their coincidence, their zeal, and their
prudence.

"But it was still more wonderful, that about half the numerous
population took no part in the proceedings, remaining motionless, while
the others fulfilled the functions required. The wax-workers, in a
state of absolute repose, recalled our former observations. Gorged
with the honey we had put within their reach, and continuing in this
condition during twenty-four hours, wax was formed under their rings,
and was now ready to be put in operation. To our great satisfaction,
we soon saw a little foundation-wall rising on one of the slips that
we had prepared to receive the superstructure. No obstacle was offered
to the progress of our observations; and for the second time we beheld
both the undertaking of the founder-bee, and the successive labours
of several wax-workers, in forming the foundation-wall. Would that my
readers could share the interest which the view of these architects
inspired!

"This foundation, originally very small, was enlarged as the work
required; while they excavated on one side a hollow, of about the width
of a common cell, and on the opposite surface two others somewhat
more elongated. The middle of the single cell corresponded exactly to
the partition separating the latter: the arches of these excavations,
projecting by the accumulation of wax, were converted into ridges in a
straight line; whence the cells of the first row were composed of five
sides, considering the slip as one side, and those of the second row,
of six sides.

[Illustration: Foundation-wall enlarged, and the Cells commenced.]

"The interior conformation of the cavities, apparently, was derived
from the position of their respective outlines. It seemed that the
bees, endowed with an admirable delicacy of feeling, directed their
teeth principally to the place where the wax was thickest; that is, the
parts where other workers on the opposite side had accumulated it; and
this explains why the bottom of the cell is excavated in an angular
direction behind the projection on the sides of which the sides of the
corresponding cells are to rise. The largest of the excavations, which
was opposite to three others, was divided into three parts, while the
excavations of the first row on the other face, applied against this
one, were composed of only two.

"In consequence of the manner in which the excavations were opposed
to each other, those of the second row, and all subsequent, partially
applied to three cavities, were composed of three equal diamond-shaped
lozenges. I may here remark, that each part of the labour of bees
appears the natural result of what has preceded it: therefore, chance
has no share in these admirable combinations.

"A foundation-wall rose above the slip like a minute vertical
partition, five or six lines long, two lines high, but only half a
line in thickness; the edge circular, and the surface rough. Quitting
the cluster among the combs, a nurse-bee mounted the slip, turned
around the block, and visiting both sides, began to work actively
in the middle. It removed as much wax with its teeth as might equal
the diameter of a common cell; and after kneading and moistening the
particles, deposited them on the edge of the excavation. This insect
having laboured some seconds, retired, and was soon replaced by
another; a third continued the work, raising the margin of the edges,
now projecting from the cavity, and with assistance of its teeth and
feet fixing the particles, so as to give these edges a straighter form.
More than twenty bees successively participated in the same work; and
when the cavity was little above a line and a half in height, though
equalling a cell in width, a bee left the swarm, and after encircling
the block, commenced its operations on the opposite face, where
yet untouched. But its teeth acting only on one half of this side,
the hollow which it formed was opposite to only one of the slight
prominences bordering the first cavity. Nearly at the same time another
worker began on the right of the face that had been untouched, wherein
both were occupied in forming cavities which may be designed the second
and third; and they also were replaced by substitutes. These two latter
cavities were separated only by the common margin, framed of particles
of wax withdrawn from them; which margin corresponded with the centre
of the cavity on the opposite surface. The foundation-wall itself was
still of insufficient dimensions to admit the full diameter of a cell:
but while the excavations were deepened, wax-workers, extracting their
scales of wax, applied them in enlarging its circumference; so that it
rose nearly two lines further around the circular arch. The nurse-bees,
which appeared more especially charged with sculpturing the cells,
being then enabled to continue their outlines, prolonged the cavities,
and heightened their margins on the new addition of wax.

"The arch, formed by the edge of each of these cavities, was next
divided as by two equal chords, in the line of which the bees formed
stages or projecting borders, or margins meeting at an obtuse angle:
the cavities now had four margins, two lateral and perpendicular to the
supporting slip, and two oblique, which were shorter.

"Meantime, it became more difficult to follow the operations of the
bees, from their frequently interposing their heads between the eye of
the observer and the bottom of the cell; but the partition, whereon
their teeth laboured, had become so transparent as to expose what
passed on the other side.

"The cavities of which we speak formed the bottom of the first three
cells; and while the bees engaged were advancing them to perfection,
other workers commenced sketching a second row of cells above the
first, and partly behind those in front--for, in general, their labour
proceeds by combination. We cannot say, 'When bees have finished
this cell, they will begin new ones;' but, 'while particular workers
advance a certain portion, we are certain that others will carry on
the adjacent cells.' Further, the work begun on one face of the comb
is already the commencement of that which is to follow on the reverse.
All this depends on a reciprocal relation, or a mutual connexion of the
parts, rendering the whole subservient to each other. It is undoubted,
therefore, that slight irregularities on the front will affect the form
of the cells on the back of the comb."[AR]

When they have in this manner worked the bottoms of the first row of
cells into the required forms, some of the nurse-bees finish them
by imparting a sort of polish, while others proceed to cut out the
rudiments of a second row from a fresh wall of wax which has been built
in the meanwhile by the wax-workers, and also on the opposite side of
this wall; for a comb of cells is always double, being arranged in two
layers, placed end to end. The cells of this second row are engrafted
on the borders of cavities hollowed out in the wall, being founded
by the nurse-bees, bringing the contour of all the bottoms, which is
at first unequal, to the same level; and this level is kept uniform
in the margins of the cells till they are completed. At first sight
nothing appears more simple than adding wax to the margins; but from
the inequalities occasioned by the shape of the bottom, the bees must
accumulate wax on the depressions, in order to bring them to a level.
It follows accordingly that the surface of a new comb is not quite
flat, there being a progressive <DW72> produced as the work proceeds,
and the comb being therefore in the form of a lens, the thickness
decreasing towards the edge, and the last-formed cells being shallower
or shorter than those preceding them. So long as there is room for the
enlargement of the comb, this thinning of its edge may be remarked;
but as soon as the space within the hive prevents its enlargement, the
cells are made equal, and two flat and level surfaces are produced.

M. Huber observed, that while sketching the bottom of a cell, before
there was any upright margin on the reverse, their pressure on the
still soft and flexible wax gave rise to a projection, which sometimes
caused a breach of the partition. This, however, was soon repaired,
but a slight prominence always remained on the opposite surface, to
the right and left of which they placed themselves to begin a new
excavation; and they heaped up part of the materials between the two
flutings formed by their labour. The ridge thus formed becomes a guide
to the direction which the bees are to follow for their vertical furrow
of the front cell.

We have already seen that the first cell determines the place of all
that succeed it, and two of these are never, in ordinary circumstances,
begun in different parts of the hive at the same time, as is alleged
by some early writers. When some rows of cells, however, have been
completed in the first comb, two other foundation-walls are begun, one
on each side of it, at the exact distance of one-third of an inch,
which is sufficient to allow two bees employed on the opposite cells to
pass each other without jostling. These new walls are also parallel to
the former; and two more are afterwards begun exterior to the second,
and at the same parallel distance. The combs are uniformly enlarged,
and lengthened in a progression proportioned to the priority of their
origin; the middle comb being always advanced beyond the two adjoining
ones by several rows of cells, and these again beyond the ones exterior
to them. Did the bees lay the foundations of all their combs at the
same time, they would not find it easy to preserve parallelism and an
equality in their distances. It may be remarked further, that beside
the vacancies of half an inch between the cells, which form what we
call the highways of the community, the combs are pierced in several
places with holes which serve as postern-gates for easy communication
from one to another, to prevent loss of time in going round. The equal
distance between the combs is of more importance to the welfare of the
hive than might at first appear; for were they too distant, the bees
would be so scattered and dispersed, that they could not reciprocally
communicate the heat indispensable for hatching the eggs and rearing
the young. If the combs, on the other hand, were closer, the bees could
not traverse the intervals with the freedom necessary to facilitate the
work of the hive. On the approach of winter, they sometimes elongate
the cells which contain honey, and thus contract the intervals between
the combs. But this expedient is in preparation for a season when it
is important to have copious magazines, and when, their activity being
relaxed, it is unnecessary for their communications to be so spacious
and free. On the return of spring, the bees hasten to contract the
elongated cells, that they may become fit for receiving the eggs which
the queen is about to deposit, and in this manner they re-establish the
regular distance.[AS]

We are indebted to the late Dr. Barclay of Edinburgh, well known as an
excellent anatomist, for the discovery that each cell in a honeycomb is
not simply composed of one wall, but consists of two. We shall give the
account of his discovery in his own words:--

"Having inquired of several naturalists whether or not they knew any
author who had mentioned that the partitions between the cells of the
honeycomb were double, and whether or not they had ever remarked such
a structure themselves, and they having answered in the negative, I
now take the liberty of presenting to the Society pieces of honeycomb,
in which the young bees had been reared, upon breaking which, it will
be clearly seen that the partitions between different cells, at the
sides and the base, are all _double_; or, in other words, that each
cell is a distinct, separate, and in some measure an independent
structure, agglutinated only to the neighbouring cells; and that when
the agglutinating substance is destroyed, each cell may be entirely
separated from the rest.

"I have also some specimens of the cells formed by wasps, which
show that the partitions between them are also double, and that the
agglutinating substance between them is more easily destroyed than that
between the cells of the bee."[AT]


Irregularities in their Workmanship.

Though bees, however, work with great uniformity when circumstances
favour their operations, they may be compelled to vary their
proceedings. M. Huber made several ingenious experiments of this kind.
The following, mentioned by Dr. Bevan, was accidental, and occurred to
his friend Mr. Walond. "Inspecting his bee-boxes at the end of October,
1817, he perceived that a centre comb, burthened with honey, had
separated from its attachments, and was leaning against another comb
so as to prevent the passage of the bees between them. This accident
excited great activity in the colony; but its nature could not be
ascertained at the time. At the end of a week, the weather being cold,
and the bees clustered together Mr. Walond observed, through the window
of the box, that they had constructed two horizontal pillars betwixt
the combs alluded to, and had removed so much of the honey and wax from
the top of each as to allow the passage of a bee: in about ten days
more there was an uninterrupted thoroughfare; the detached comb at its
upper part had been secured by a strong barrier, and fastened to the
window with the spare wax. This being accomplished, the bees removed
the horizontal pillars first constructed, as being of no further
use."[AU]

A similar anecdote is told by M. Huber. "During the winter," says he,
"a comb in one of my bell-glass hives, having been originally insecure,
fell down, but preserved its position parallel to the rest. The bees
were unable to fill up the vacuity left above it, because they do
not build combs of old wax, and none new could be then obtained. At
a more favourable season they would have engrafted a new comb on the
old one; but now their provision of honey could not be spared for
the elaboration of this substance, which induced them to insure the
stability of the comb by another process.

"Crowds of bees taking wax from the lower part of other combs, and even
gnawing it from the surface of the orifices of the deepest cells, they
constructed so many irregular pillars, joists, or buttresses, between
the sides of the fallen comb, and others on the glass of the hive. All
these were artificially adapted to localities. Neither did they confine
themselves to repairing the accidents which their works had sustained.
They seemed to profit by the warning to guard against a similar
casualty.

"The remaining combs were not displaced; therefore, while solidly
adhering by the base, we were greatly surprised to see the bees
strengthen their principal fixtures with old wax. They rendered them
much thicker than before, and fabricated a number of new connections,
to unite them more firmly to each other and to the sides of their
dwelling. All this passed in the middle of January, a time that these
insects commonly keep in the upper part of their hive, and when work is
no longer seasonable."[AV]

M. Huber the younger shrewdly remarks, that the tendency to symmetry
observable in the architecture of bees does not hold so much in small
details as in the whole work, because they are sometimes obliged to
adapt themselves to particular localities. One irregularity leads on
to another, and it commonly arises from mere accident, or from design
on the part of the proprietor of the bees. By allowing, for instance,
too little interval between the spars for receiving the foundation of
the combs, the structure has been continued in a particular direction.
The bees did not at first appear to be sensible of the defect, though
they afterwards began to suspect their error, and were then observed to
change their line of work till they gained the customary distance. The
cells having been by this change of direction in some degree curved,
the new ones which were commenced on each side of it, by being built
everywhere parallel to it, partook of the same curvature. But the bees
did not relish such approaches to the "line of beauty," and exerted
themselves to bring their buildings again into the regular form.

In consequence of several irregularities which they wished to correct,
the younger Huber has seen bees depart from their usual practice, and
at once lay on a spar two foundation-walls not in the same line. They
could consequently neither be enlarged without obstructing both, nor
from their position could the edges unite, had they been prolonged.
The little architects, however, had recourse to a very ingenious
contrivance: they curved the edges of the two combs, and brought them
to unite so neatly that they could be both prolonged in the same line
with ease; and when carried to some little distance, their surface
became quite uniform and level.

"Having seen bees," says the elder Huber, "work both up and down, I
wished to try to investigate whether we could compel them to construct
their combs in any other direction. We endeavoured to puzzle them with
a hive glazed above and below, so that they had no place of support
but the upright sides of their dwelling; but, betaking themselves
to the upper angle, they built combs perpendicular to one of these
sides, and as regularly as those which they usually build under a
horizontal surface. The foundations were laid on a place which does
not serve naturally for the base, yet, except in the difference
of direction, the first row of cells resembled those in ordinary
hives, the others being distributed on both faces, while the bottoms
alternately corresponded with the same symmetry. I put the bees to a
still greater trial. As they now testified their inclination to carry
their combs, by the shortest way, to the opposite side of the hive (for
they prefer uniting them to wood, or a surface rougher than glass), I
covered it with a pane. Whenever this smooth and slippery substance was
interposed between them and the wood, they departed from the straight
line hitherto followed, and bent the structure of their comb at a
right angle to what was already made, so that the prolongation of the
extremity might reach another side of the hive, which had been left
free.

"Varying this experiment in several ways, I saw the bees constantly
change the direction of their combs, when I presented to them a surface
too smooth to admit of their clustering on it. They always sought the
wooden sides. I thus compelled them to curve the combs in the strangest
shapes, by placing a pane at a certain distance from their edges. These
results indicate a degree of instinct truly wonderful. They denote even
more than instinct: for glass is not a substance against which bees can
be warned by nature. In trees, their natural abode, there is nothing
that resembles it, or with the same polish. The most singular part of
their proceeding is changing the direction of the work before arriving
at the surface of the glass, and while yet at a distance suitable for
doing so. Do they anticipate the inconvenience which would attend any
other mode of building? No less curious is the plan adopted by the
bee for producing an angle in the combs: the wonted fashion of their
work, and the dimensions of the cells, must be altered. Therefore, the
cells on the upper or convex side of the combs are enlarged; they are
constructed of three or four times the width of those on the opposite
surface. How can so many insects, occupied at once on the edges of the
combs, concur in giving them a common curvature from one extremity to
the other? How do they resolve on establishing cells so small on one
side, while dimensions so enlarged are bestowed on those of the other?
And is it not still more singular, that they have the art of making a
correspondence between cells of such reciprocal discrepance? The bottom
being common to both, the tubes alone assume a taper form. Perhaps no
other insect has afforded a more decisive proof of the resources of
instinct, when compelled to deviate from the ordinary course.

"But let us study them in their natural state, and there we shall find
that the diameter of their cells must be adapted to the individuals
which shall be bred in them. The cells of males have the same figure,
the same number of lozenges and sides, as those of workers, and angles
of the same size. Their diameter is 3-1/3 lines, while those of workers
are only 2-2/5.

"It is rarely that the cells of males occupy the higher part of the
combs. They are generally in the middle or on the sides, where they
are not isolated. The manner in which they are surrounded by other
cells alone can explain how the transition in size is effected. When
the cells of males are to be fabricated under those of workers, the
bees make several rows of intermediate cells, whose diameter augments
progressively, until gaining that proportion proper to the cells
required; and in returning to those of workers, a lowering is observed
in a manner corresponding.

"Bees, in preparing the cells of males, previously establish a block or
lump of wax on the edge of their comb, thicker than is usually employed
for those of workers. It is also made higher, otherwise the same order
and symmetry could not be preserved on a larger scale.

"Several naturalists notice the irregularities in the cells of bees
as so many defects. What would have been their astonishment had
they observed that part of them are the result of calculation? Had
they followed the imperfection of their organs, some other means
of compensating them would have been granted to the insects. It is
much more surprising that they know how to quit the ordinary route,
when circumstances demand the construction of enlarged cells; and,
after building thirty or forty rows of them, to return to the proper
proportions from which they have departed by successive reductions.
Bees also augment the dimensions of their cells when there is an
opportunity for a great collection of honey. Not only are they then
constructed of a diameter much exceeding that of the common cells, but
they are elongated throughout the whole space admitting it. A great
portion of irregular comb contains cells an inch, or even an inch and a
half, in depth.

"Bees, on the contrary, sometimes are induced to shorten their cells.
When wishing to prolong an old comb, whose cells have received their
full dimensions, they gradually reduce the thickness of its edges,
by gnawing down the sides of the cells, until they restore it to its
original lenticular form. They add a waxen block around the whole
circumference, and on the edge of the comb construct pyramidal bottoms,
such as those fabricated on ordinary occasions. It is a certain fact,
that a comb never is extended in any direction unless the bees have
thinned the edges, which are diminished throughout a sufficient space
to remove any angular projection.

"The law which obliges these insects partly to demolish the cells on
the edges of the comb before enlarging it, unquestionably demands more
profound investigation. How can we account for instinct leading them to
undo what they have executed with the utmost care? The wonted regular
gradation which may be necessary for new cells, subsists among those
adjoining the edges of a comb recently constructed. But afterwards,
when those on the edge are deepened like the cells of the rest of the
surface, the bees no longer preserve the decreasing gradation which is
seen in the new combs."[AW]


The Finishing of the Cells.

While the cells are building they appear to be of a dull white colour,
soft, even, though not smooth, and translucent; but in a few days they
become tinged with yellow, particularly on the interior surface; and
their edges, from being thin, uniform, and yielding, become thicker,
less regular, more heavy, and so firm that they will bend rather
than break. New combs break on the slightest touch. There is also a
glutinous substance observable around the orifices of the yellow cells,
of reddish colour, unctuous, and odoriferous. Threads of the same
substance are applied all around the interior of the cells, and at the
summit of their angles, as if it were for the purpose of binding and
strengthening the walls. These yellow cells also require a much higher
temperature of water to melt them than the white ones.

It appeared evident, therefore, that another substance, different from
wax, had been employed in varnishing the orifices, and strengthening
the interior of the cells. M. Huber, by numerous experiments,
ascertained the resinous threads lining the cells, as well as the
resinous substance around their orifice, to be propolis; for he traced
them, as we mentioned in our account of propolis, from the poplar
buds where they collected it, and saw them apply it to the cells; but
the yellow colour is not imparted by propolis, to which it bears no
analogy. We are, indeed, by no means certain what it is, though it
was proved by experiment not to arise from the heat of the hives, nor
from emanations of honey, nor from particles of pollen. Perhaps it may
be ascribed to the bees rubbing their teeth, feet, and other parts of
their body, on the surfaces where they seem to rest; or to their tongue
(haustellum) sweeping from right to left like a fine pliant pencil,
when it appears to leave some sprinkling of a transparent liquid.

Besides painting and varnishing their cells in this manner, they take
care to strengthen the weaker part of their edifice by means of a
mortar composed of propolis and wax, and named _pissoceros_[AX] by the
ancients who first observed it, though Reaumur was somewhat doubtful
respecting the existence of such a composition. We are indebted to the
shrewd observations of Huber for a reconcilement of the Roman and the
French naturalists. The details which he has given of his discovery are
perhaps the most interesting in his delightful book.

"Soon," he says, "after some new combs had been finished in a hive,
manifest disorder and agitation prevailed among the bees. They seemed
to attack their own works. The primitive cells, whose structure we
had admired, were scarcely recognizable. Thick and massive walls,
heavy, shapeless pillars, were substituted for the slight partitions
previously built with such regularity. The substance had changed along
with the form, being composed apparently of wax and propolis. From
the perseverance of the workers in their devastation, we suspected
that they proposed some useful alteration of their edifices; and our
attention was directed to the cells least injured. Several were yet
untouched; but the bees soon rushed precipitately on them, destroyed
the tubes, broke down the wax, and threw all the fragments about.
But we remarked that the bottom of the cells of the first row were
spared; neither were the corresponding parts on both faces of the comb
demolished at the same time. The bees laboured at them alternately,
leaving some of the natural supports, otherwise the comb would have
fallen down, which was not their object: they wished, on the contrary,
to provide it a more solid base, and to secure its union to the vault
of the hive, with a substance whose adhesive properties infinitely
surpassed those of wax. The propolis employed on this occasion had
been deposited in a mass over a cleft of the hive, and had hardened
in drying, which probably rendered it more suitable for the purpose.
But the bees experienced some difficulty in making any impression on
it; and we thought, as also had appeared to M. de Reaumur, that they
softened it with the same frothy matter from the tongue which they use
to render wax more ductile.

"We very distinctly observed the bees mixing fragments of old wax with
the propolis, kneading the two substances together to incorporate
them; and the compound was employed in rebuilding the cells that had
been destroyed. But they did not now follow their ordinary rules of
architecture, for they were occupied by the solidity of their edifices
alone. Night intervening, suspended our observations, but next morning
confirmed what we had seen.

"We find, therefore, that there is an epoch in the labour of bees,
when the upper foundation of their combs is constructed simply of wax,
as Reaumur believed; and that, after all the requisite conditions
have been attained, it is converted to a mixture of wax and propolis,
as remarked by Pliny so many ages before us. Thus is the apparent
contradiction between these two great naturalists explained. But this
is not the utmost extent of the foresight of these insects. When they
have plenty of wax, they make their combs the full breadth of the hive,
and solder them to the glass or wooden sides, by structures more or
less approaching the form of cells, as circumstances admit. But should
the supply of wax fail before they have been able to give sufficient
diameter to the combs whose edges are rounded, large intervals remain
between them and the upright sides of the hive, and they are fixed
only at the top. Therefore, did not the bees provide against it, by
constructing great pieces of wax mixed with propolis, in the intervals,
they might be borne down by the weight of the honey. These pieces are
of irregular shape, strangely hollowed out, and their cavities void of
symmetry."[AY]

It is remarked by the lively Abbe la Pluche, that the foundations of
our houses sink with the earth on which they are built, the walls
begin to stoop by degrees, they nod with age, and bend from their
perpendicular;--lodgers damage everything, and time is continually
introducing some new decay. The mansions of the bees, on the contrary,
grow stronger the oftener they change inhabitants. Every bee-grub,
before its metamorphosis into a nymph, fastens its skin to the
partitions of its cell, but in such a manner as to make it correspond
with the lines of the angle, and without in the least disturbing the
regularity of the figure. During summer, accordingly, the same lodging
may serve for three or four grubs in succession; and in the ensuing
season it may accommodate an equal number. Each grub never fails to
fortify the panels of its chamber by arraying them with its spoils,
and the contiguous cells receive a similar augmentation from its
brethren.[AZ] Reaumur found as many as seven or eight of these skins
spread over one another: so that all the cells being incrusted with six
or seven coverings, well dried and cemented with propolis, the whole
fabric daily acquires a new degree of solidity.

It is obvious, however, that by a repetition of this process the cell
might be rendered too contracted; but in such a case the bees know well
how to proceed, by turning the cells to other uses, such as magazines
for bee-bread and honey. It has been remarked, however, that in the
hive of a new swarm, during the months of July and August, there are
fewer small bees or nurse-bees than in one that has been tenanted four
or five years. The workers, indeed, clean out the cell the moment that
a young bee leaves its cocoon, but they never detach the silky film
which it has previously spun on the walls of its cell. But though honey
is deposited after the young leave the cells, the reverse also happens;
and accordingly, when bees are bred in contracted cells, they are by
necessity smaller, and constitute, in fact, the important class of
nurse-bees.

We are not disposed, however, to go quite so far as an American
periodical writer, who says, "Thus we see that the contraction of
the cell may diminish the size of a bee, _even to the extinction of
life_, just as the contraction of a Chinese shoe reduces the foot even
to uselessness."[BA] We know, on the contrary, that the queen-bee
will not deposit eggs in a cell either too small or too large for the
proper rearing of the young. In the case of large cells, M. Huber took
advantage of a queen that was busy depositing the eggs of workers to
remove all the common cells adapted for their reception, and left only
the larger cells appropriated for males. As this was done in June, when
bees are most active, he expected that they would have immediately
repaired the breaches he had made; but to his great surprise they did
not make the slightest movement for that purpose. In the meanwhile the
queen, being oppressed by her eggs, was obliged to drop them about at
random, preferring this to depositing them in the male cells, which she
knew to be too large. At length she did deposit six eggs in the large
cells, which were hatched as usual three days after. The nurse-bees,
however, seemed to be aware that they could not be reared there, and
though they supplied them with food, did not attend to them regularly.
M. Huber found that they had been all removed from the cells during the
night, and the business both of laying and nursing was at a complete
stand for twelve days, when he supplied them again with a comb of small
cells, which the queen almost immediately filled with eggs, and in some
cells she laid five or six.

[Illustration]

[The accompanying illustration exhibits these three kinds of bees,
namely, the Queen, the Drone, and the Worker, together with the cells
which they respectively inhabit. Fig. 1 shows the queen-bee as she
appears when in command of a hive. When she first issues from the
royal cell, she is much smaller in the body, and an inexperienced
observer might have some difficulty in distinguishing her from an
ordinary worker. But any one who has been accustomed to bees can pick
her out as soon as his eyes rest upon her. Her body is rather larger
and narrower than those of the workers, and the wings are shorter in
proportion, slightly crossing at the tips when she is at rest. Fig. 2
represents the common worker-bee, which, as has already been mentioned,
is simply an undeveloped female. Fig. 3 is the male or drone-bee, which
is easily distinguishable, even by a novice. He is larger, stouter,
and heavier built than the female; his eyes are so enormous that they
seem to occupy nearly the entire head, and he has some well-defined
tufts of hair on the end of the abdomen. He can even be detected by
the ear, as he flies, the deep droning hum being quite unlike the
fussy, business-like sound produced by the worker. Fig. 4 represents
one of the royal cells, a little reduced in size. In making this cell,
the bees lose sight of their habitual economy of wax, and use enough
material for fifty ordinary cells. It is probable that the great size
of the cell enables the inclosed insect to expand, and so to be capable
of becoming the mother as well as the ruler of her subjects. The royal
cell is always placed at the edge of a comb, so as not to interfere
with the other cells, which contain honey, bee-bread, and grubs; and
in each hive there are generally several of these cells in different
stages of structure. Figs. 5 and 6 represent the proportionate sizes of
the cells which contain the drone and worker bees.]

       *       *       *       *       *

The architecture of the hive, which we have thus detailed, is that of
bees receiving the aid of human care, and having external coverings of
a convenient form, prepared for their reception. In this country bees
are not found in a wild state; though it is not uncommon for swarms
to stray from their proprietors. But these stray swarms do not spread
colonies through our woods, as they are said to do in America. In the
remoter parts of that continent there are no wild bees. They precede
civilization; and thus when the Indians observe a swarm they say, "The
white man is coming." There is evidence of bees having abounded in
these islands, in the earlier periods of our history; and Ireland is
particularly mentioned by the Venerable Bede as being "rich in milk and
honey."[BB] The hive-bee has formed an object of economical culture in
Europe at least for two thousand years; and Varro describes the sort of
hives used in his time, 1870 years ago. We are not aware, however, that
it is now to be found wild in the milder clime of Southern Europe, any
more than it is in our own island.

The wild bees of Palestine principally hived in rocks. "He made him,"
says Moses, "to suck honey out of the rock."[BC] "With honey out of
the rock," says the Psalmist, "should I have satisfied thee."[BD] In
the caves of Salsette and Elephanta, at the present day, they hive in
the clefts of the rocks, and the recesses among the fissures, in such
numbers as to become very troublesome to visitors. Their nests hang in
innumerable clusters.[BE]

We are told of a little black stingless bee found in the island of
Guadaloupe, which hives in hollow trees or in the cavities of rocks by
the sea-side, and lays "up honey in cells about the size and shape
of pigeons' eggs. These cells are of a black or deep-violet colour,
and so joined together as to leave no space between them. They hang
in clusters almost like a bunch of grapes."[BF] The following are
mentioned by Lindley as indigenous to Brazil. "On an excursion towards
Upper Tapagippe," says he, "and skirting the dreary woods which extend
to the interior, I observed the trees more loaded with bees' nests than
even in the neighbourhood of Porto Seguro. They consist of a ponderous
shell of clay, cemented similarly to martins' nests, swelling from
high trees about a foot thick, and forming an oval mass full two feet
in diameter. When broken, the wax is arranged as in our hives, and the
honey abundant."[BG]

Captain Basil Hall found in South America the hive of a honey-bee very
different from the Brazilian, but nearly allied to, if not the same as,
that of Guadaloupe. "The hive we saw opened," he says, "was only partly
filled, which enabled us to see the economy of the interior to more
advantage. The honey is not contained in the elegant hexagonal cells of
our hives, but in wax bags, not quite so large as an egg. These bags or
bladders are hung round the sides of the hive, and appear about half
full; the quantity being probably just as great as the strength of the
wax will bear without tearing. Those near the bottom, being better
supported, are more filled than the upper ones. In the centre of the
lower part of the hive we observed an irregularly-shaped mass of comb,
furnished with cells like those of our bees, all containing young ones
in such an advanced state, that, when we broke the comb, and let them
out, they flew merrily away."

Clavigero, in his 'History of Mexico,' evidently describing the same
species of bee, says it abounds in Yucatan, and makes the honey of
Estabentum, the finest in the world, and which is taken every two
months. He mentioned another species of bee, smaller in size, and also
without a sting, which forms its nest of the shape of a sugar-loaf, and
as large or larger. These are suspended from trees, particularly from
the oak, and are much more populous than our common hives.

Wild honey-bees of some species appear also to abound in Africa. Mr.
Park, in his second volume of travels, tells us that some of his
associates imprudently attempted to rob a numerous hive of its honey,
when the exasperated bees, rushing out to defend their property,
attacked their assailants with great fury, and quickly compelled the
whole company to fly.

At the Cape of Good Hope the bees themselves must be less formidable,
or more easily managed, as their hives are sought for with avidity.
Nature has there provided man with a singular and very efficient
assistant in a bird, most appropriately named the honey-guide
(_Indicator major_, Veillot; _Cuculus indicator_, Latham). The
honey-guide, it is said, so far from being alarmed at the presence of
man, appears anxious to court his acquaintance, and flits from tree
to tree with an expressive note of invitation, the meaning of which
is both well known to the colonists and the Hottentots. A person thus
invited by the honey-guide seldom refuses to follow it onward till
it stops, as it is certain to do, at some hollow tree containing a
bee-hive, usually well stored with honey and wax. It may be that
the bird finds itself inadequate to the attack of a legion of bees,
or to penetrate into the interior of the hive, and is thence led to
invite an agent more powerful than itself. The person invited, indeed,
always leaves the bird a share of the spoil, as it would be considered
sacrilege to rob it of its due, or in any way to injure so sacred a
bird.

Useful, however, as is the honey-guide, it must always be carefully
watched, and the traveller must not follow it without keeping his eyes
well open. For although, as a general fact, the bird will lead its
followers to honey, it has a strange habit of leading them to the spot
where lies hidden some dangerous animal. Sometimes it brings them to
a rhinoceros, wallowing in a mud pool. Sometimes it directs them to
a solitary buffalo, one of the most dangerous animals that Southern
Africa produces, and one which the natives fear but little less than
the lion itself. And more than once the too-confiding traveller has
followed the honey-guide, and been led to a spot where was lying one of
the venomous serpents.

The Americans, who have not the African honey-guide, employ several
well-known methods to track bees to their hives. One of the most
common though ingenious modes is to place a piece of bee-bread on a
flat surface, a tile for instance, surrounding it with a circle of wet
white paint. The bee, whose habit it is always to alight on the edge
of any plane, has to travel through the paint to reach the bee-bread.
When, therefore, she flies off, the observer can track her by the
white on her body. The same operation is repeated at another place,
at some distance from the first, and at right angles to the bee-line
just ascertained. The position of the hive is easily determined, for it
lies in the angle made by the intersection of the bee-lines. Another
method is described in the 'Philosophical Transactions for 1721.' The
bee-hunter decoys, by a bait of honey, some of the bees into his trap,
and when he has secured as many as he judges will suit his purpose,
he encloses one in a tube, and, letting it fly, marks its course by
a pocket-compass. Departing to some distance, he liberates another,
observes its course, and in this manner determines the position of the
hive, upon the principle already detailed. These methods of bee-hunting
depend upon the insect's habit of always flying in a right line to its
home. Those who have read Cooper's tale of the 'Prairie' must well
remember the character of the bee-hunter, and the expression of "lining
a bee to its hive."

In reading these and similar accounts of the bees of distant parts of
the world, we must not conclude that the descriptions refer to the
same species as the common honey-bee. There are numerous species of
social bees, which, while they differ in many circumstances, agree in
the practice of storing up honey, in the same way as we have numerous
species of the mason-bee and of the humble-bee.




_CHAPTER VII._

CARPENTRY OF TREE-HOPPERS AND SAW-FLIES.


The operations of an insect in boring into a leaf or a bud to form
a lodgment for its eggs appear very simple. The tools, however, by
which these effects are performed are very complicated and curious.
In the case of gall-flies (_Cynips_), the operation itself is not so
remarkable as its subsequent chemical effects. These effects are so
different from any others that may be classed under the head of Insect
Architecture, that we shall reserve them for the latter part of this
volume, although, with reference to the use of galls, the protection
of eggs and larvae, they ought to find a place here. We shall, however,
at present confine ourselves to those which simply excavate a nest,
without producing a tumour.

The first of these insects which we shall mention is celebrated for
its song, by the ancient Greek poets, under the name of _Tettix_.
The Romans called it _Cicada_, which we sometimes, but erroneously,
translate "grasshopper;" for the grasshoppers belong to an entirely
different order of insects. We shall, therefore, take the liberty of
calling the Cicadae _Tree-hoppers_, to which the cuckoo-spit insect
(_Tettigonia spumaria_, Oliv.) is allied; but there is only one of the
true Cicadae hitherto ascertained to be British, namely, the _Cicada
haematodes_ (Linn.), which was discovered in the New Forest, Hampshire,
by Mr. Daniel Bydder.

M. Reaumur was exceedingly anxious to study the economy of these
insects; but they not being indigenous in the neighbourhood of Paris,
he commissioned his friends to send him some from more southern
latitudes, and he procured in this way specimens not only from the
South of France and from Italy, but also from Egypt. From these
specimens he has given the best account of them yet published; for
though, as he tells us, he had never had the pleasure of seeing one
of them alive, the most interesting parts of their structure can be
studied as well in dead as in living specimens. We ourselves possess
several specimens from New Holland, upon which we have verified some of
the more interesting observations of Reaumur.

Virgil tells us that in his time "the cicadae burst the very shrubs
with their querulous music;"[BH] but we may well suppose that he was
altogether unacquainted with the singular instrument by means of which
they can, not poetically, but actually, cut grooves in the branches
they select for depositing their eggs. It is the male, as in the case
of birds, which fills the woods with his song; while the female, though
mute, is no less interesting to the naturalist on account of her
curious ovipositor. This instrument, like all those with which insects
are furnished by nature for cutting, notching, or piercing, is composed
of a horny substance, and is also considerably larger than the size of
the tree-hopper would proportionally indicate. It can on this account
be partially examined without a microscope, being, in some of the
larger species, no less than five lines[BI] in length.

The ovipositor, or auger (_tariere_), as Reaumur calls it, is lodged in
a sheath which lies in a groove of the terminating ring of the belly.
It requires only a very slight pressure to cause the instrument to
protrude from its sheath, when it appears to the naked eye to be of
equal thickness throughout, except at the point, where it is somewhat
enlarged and angular, and on both sides finely indented with teeth. A
more minute examination of the sheath demonstrates that it is composed
of two horny pieces slightly curved, and ending in the form of an
elongated spoon, the concave part of which is adapted to receive the
convex end of the ovipositor.

When the protruded instrument is further examined with a microscope,
the denticulations, nine in number on each side, appear strong, and
arranged with great symmetry, increasing in fineness towards the point,
where there are three or four very small ones, beside the nine that
are more obvious. The magnifier also shows that the instrument itself,
which appeared simple to the naked eye, is, in fact, composed of three
different pieces; two exterior armed with the teeth before mentioned,
denominated by Reaumur files (_limes_), and another pointed like a
lancet, and not denticulated. The denticulated pieces, moreover, are
capable of being moved forwards and backwards, while the centre one
remains stationary; and as this motion is effected by pressing a pin
or the blade of a knife over the muscles on either side at the origin
of the ovipositor, it may be presumed that those muscles are destined
for producing similar movements when the insect requires them. By means
of a finely-pointed pin carefully introduced between the pieces, and
pushed very gently downwards, they may be, with no great difficulty,
separated in their whole extent.

The contrivance by which those three pieces are held united, while at
the same time the two files can be easily put in motion, is similar
to those of our own mechanical inventions, with this difference, that
no human workman could construct an instrument of this description
so small, fine, exquisitely polished, and fitting so exactly. We
should have been apt to form the grooves in the central piece, whereas
they are scooped out in the handles of the files, and play upon two
projecting ridges in the central piece, by which means this is rendered
stronger. M. Reaumur discovered that the best manner of showing the
play of this extraordinary instrument is to cut it off with a pair of
scissors near its origin, and then, taking it between the thumb and
the finger at the point of section, work it gently to put the files in
motion.

Beside the muscles necessary for the movement of the files, the handle
of each is terminated by a curve of the same hard horny substance as
itself, which not only furnishes the muscles with a sort of lever, but
serves to press, as with a spring, the two files close to the central
piece, as is shown in the lower figure.

M. Pontedera, who studied the economy of the tree-hoppers with some
care, was anxious to see the insect itself make use of the ovipositor
in forming grooves in wood, but found that it was so shy and easily
alarmed, that it took to flight whenever he approached; a circumstance
of which Reaumur takes advantage, to soothe his regret that the insects
were not indigenous in his neighbourhood. But of their workmanship,
when completed, he had several specimens sent to him from Provence and
Languedoc by the Marquis de Caumont.

[Illustration: Ovipositors, with files, of Tree-hopper, magnified.]

[Illustration: Excavations for eggs of Tree-hopper, with the chip-lids
raised.]

The gall-flies, when about to deposit their eggs, select growing plants
and trees; but the tree-hoppers, on the contrary, make choice of dead,
dried branches, for the mother seems to be aware that moisture would
injure her progeny. The branch, commonly a small one, in which eggs
have been deposited, may be recognised by being covered with little
oblong elevations caused by small splinters of the wood, detached at
one end, but left fixed at the other, by the insect. These elevations
are for the most part in a line, rarely in a double line, nearly at
equal distances from each other, and form a lid to a cavity in the wood
about four lines in length, containing from four to ten eggs. It is to
be remarked that the insect always selects a branch of such dimensions
that it can get at the pith, not because the pith is more easily
bored, for it does not penetrate into it all, but to form a warm and
safe bed for the eggs. M. Pontedera says, that when the eggs have been
deposited, the insect closes the mouth of the hole with a gum capable
of protecting them from the weather; but M. Reaumur thinks this only a
fancy, as, out of a great number which he examined, he could discover
nothing of the kind. Neither is such a protection wanted; for the woody
splinters above mentioned furnish a very good covering.

The grubs hatch from these eggs (of which, M. Pontedera says, one
female will deposit from five to seven hundred), issue from the
same holes through which the eggs have been introduced, and betake
themselves to the ground to feed on the roots of plants. They are not
transformed into chrysalides, but into active nymphs, remarkable for
their fore limbs, which are thick, strong, and furnished with prongs
for digging; and when we are told, by Dr. Le Ferve, that they make
their way easily into hard stiff clay, to the depth of two or three
feet, we perceive how necessary to them such a conformation must be.


Saw-flies.

An instrument for cutting grooves in wood, still more ingeniously
contrived than that of the tree-hopper, was first observed by
Vallisnieri, an eminent Italian naturalist, in a four-winged fly, most
appropriately denominated by M. Reaumur the _saw-fly_ (_Tenthredo_) of
which many sorts are indigenous to Great Britain. The grubs from which
these flies originate are indeed but too well known, as they frequently
strip our rose, gooseberry, raspberry, and red currant trees of their
leaves, and are no less destructive to birch, alder, and willows;
while turnips and wheat suffer still more seriously by their ravages.
These grubs may readily be distinguished from the caterpillars of
moths and butterflies by having from sixteen to twenty-eight feet, by
which they usually hang to the leaf they feed on, while they coil up
the hinder part of their body in a spiral ring. The perfect flies are
distinguished by four transparent wings; and some of the most common
have a flat body of a yellow or orange colour, while the head and
shoulders are black.

In order to see the ovipositor, to which we shall for the present turn
our chief attention, a female saw-fly must be taken, and her belly
gently pressed, when a narrow slit will be observed to open at some
distance from the apex, and a short, pointed, and somewhat curved body,
of a brown colour and horny substance, will be protruded. The curved
plates which form the sides of the slit are the termination of the
sheath, in which the instrument lies concealed till it is wanted by the
insect. The appearance of this instrument, however, and its singular
structure, cannot be well understood without the aid of a microscope.

[Illustration: _a_, Ovipositor of Saw-fly, protruded from its sheath,
magnified.]

The instrument thus brought into view is a very finely-contrived
saw, made of a horny substance, and adapted for penetrating branches
and other parts of plants where the eggs are to be deposited. The
ovipositor-saw of the insect is much more complicated than any of those
employed by our carpenters. The teeth of our saws are formed in a line,
but in such a manner as to cut in two lines parallel to, and at a
small distance from, each other. This is effected by slightly bending
the points of the alternate teeth right and left, so that one-half
of the whole teeth stand a little to the right, and the other half a
little to the left. The distance of the two parallel lines thus formed
is called the _course_ of the saw, and it is only the portion of wood
which lies in the course that is cut into sawdust by the action of the
instrument. It will follow that in proportion to the thinness of a saw
there will be the less destruction of wood which may be sawed. When
cabinet-makers have to divide valuable wood into very thin leaves, they
accordingly employ saws with a narrow course, while sawyers who cut
planks use one with a broad course. The ovipositor-saw being extremely
fine, does not require the teeth to diverge much; but from the manner
in which they operate, it is requisite that they should not stand,
like those of our saws, in a straight line. The greater portion of the
edge of the instrument, on the contrary, is towards the point somewhat
concave, similar to a scythe, while towards the base it becomes a
little convex, the whole edge being nearly the shape of an Italic _f_.

[Illustration: Ovipositor-saw of Saw-fly, with rasps shown in the cross
lines.]

The ovipositor-saw of the fly is put in motion in the same way as a
carpenter's hand-saw, supposing the tendons attached to its base to
form the handle, and the muscles which put it in motion to be the
hand of the carpenter. But the carpenter can only work one saw at a
time, whereas each of these flies is furnished with two, equal and
similar, which it works at the same time--one being advanced and the
other retracted alternately. The secret, indeed, of working more saws
than one at once is not unknown to our mechanics; for two or three are
sometimes fixed in the same frame. These, however, not only all move
upwards and downwards simultaneously, but cut the wood in different
places; while the two saws of the ovipositor work in the same cut,
and consequently, though the teeth are extremely fine, the effect is
similar to a saw with a wide set.

It is important, seeing that the ovipositor-saws are so fine, that they
be not bent or separated while in operation--and this, also, nature has
provided for, by lodging the backs of the saws in a groove, formed by
two membranous plates, similar to the structure of a clasp-knife. These
plates are thickest at the base, becoming gradually thinner as they
approach the point, which the form of the saws requires. According to
Vallisnieri, it is not the only use of this apparatus to form a back
for the saws, he having discovered, between the component membranes,
two canals, which he supposes are employed to conduct the eggs of the
insect into the grooves which it has hollowed out for them.

[Illustration: Portion of a Saw-Fly's comb-toothed rasp, and saw.]

The teeth of a carpenter's saw, it may be remarked, are simple, whereas
the teeth of the ovipositor-saw are themselves denticulated with fine
teeth. The latter, also, combines at the same time the properties of a
saw and of a rasp or file. So far as we are aware, these two properties
have, never been combined in any of the tools of our carpenters. The
rasping part of the ovipositor, however, is not constructed like our
rasps, with short teeth thickly studded together, but has teeth almost
as long as those of the saw, and placed contiguous to them, on the back
of the instrument, resembling in their form and setting the teeth of a
comb, as may be seen in the figure. Of course, such observations are
conducted with the aid of a microscope.

When a female saw-fly has selected the branch of a rose-tree, or any
other, in which to deposit her eggs, she may be seen bending the end
of her belly inwards, in form of a crescent, and protruding her saw,
at the same time, to penetrate the bark or wood. She maintains this
recurved position so long as she works in deepening the groove; but
when she has attained the depth required, she unbends her body into a
straight line, and in this position works upon the place lengthways, by
applying the saw more horizontally. When she has rendered the groove
as large as she wishes, the motion of the tendons ceases, and an egg
is placed in the cavity. The saw is then withdrawn into the sheath
for about two-thirds of its length, and at the same moment a sort of
frothy liquid, similar to a lather made with soap, is dropped over the
egg, either for the purpose of gluing it in its place or sheathing it
from the action of the juices of the tree. She proceeds in the same
manner in sawing out a second groove, and so on in succession, till she
has deposited all her eggs, sometimes to the number of twenty-four.
The grooves are usually placed in a line, at a small distance from
one another, on the same branch; but sometimes the mother-fly shifts
to another, or to a different part of the branch, when she is either
scared or finds it unsuitable. She commonly, also, takes more than one
day to the work, notwithstanding the superiority of her tools. Reaumur
has seen a saw-fly make six grooves in succession, which occupied her
about ten hours and a half.

The grooves, when finished, have externally little elevation above the
level of the bark, appearing like the puncture of a lancet in the human
skin; but in the course of a day or two the part becomes first brown
and then black, while it also becomes more and more elevated. This
increased elevation is not owing to the growth of the bark, the fibres
of which, indeed, have been destroyed by the ovipositor-saw, but to the
actual growth of the egg; for when a new-laid egg of the saw-fly is
compared with one which has been several days enclosed in the groove,
the latter will be found to be very considerably the larger. This
growth of the egg is contrary to the analogy observable in the eggs
of birds, and even of most other insects; but it has its advantages.
As it continues to increase, it raises the bark more and more, and
consequently widens, at the same time, the slit at the entrance; so
that, when the grub is hatched, it finds a passage ready for its exit.
The mother-fly seems to be aware of this growth of her eggs, for she
takes care to deposit them at such distances as may prevent their
disturbing one another by their development.

Another species of saw-fly, with a yellow body and deep violet-
wings, which also selects the rose-tree, deposits her eggs in a
different manner. Instead of making a groove for each egg, like the
preceding, she forms a large single groove, sufficient for about two
dozen eggs. These eggs are all arranged in pairs, forming two straight
lines parallel to the sides of the branch. The eggs, however, though
thus deposited in a common groove, are carefully kept each in its
place; for a ridge of the wood is left to prevent those on the right
from touching those on the left--and not only so, but between each egg
of a row a thin partition of wood is left, forming a shallow cell.

[Illustration: Nest of eggs of Saw-fly, in rose-tree.]

The edges of this groove, it will be obvious, must be farther apart
than those which only contain a single egg, and, in fact, the whole is
open to inspection; but the eggs are kept from falling out, both by the
frothy glue before mentioned, and by the walls of the cells containing
them. They were observed also, by Vallisnieri, to increase in size like
the preceding.

[Illustration: _a a a_, Saw-fly of the gooseberry (_Nematus Ribesii_,
Stephens). _b_, its eggs on the nervures of a leaf. _d d_, the
caterpillars eating. _c_, one rolled up. _f_, one extended.]

[In the middle of summer, plenty of these grooves may be seen, by
looking at the under lid of leaf-stalks or delicate young twigs. Row
upon row of the grooves are sometimes found, so the all-destructive
power of the insects must indeed be great. The larvae, when full fed,
dispose of themselves in various ways. Those of the gooseberry-fly, for
example (_Nematus Ribesii_), after they have stripped the bush of its
leaves, either seek the ground or remain on the branches, and spin a
series of cocoons, attaching them to each branch by their ends. Those,
therefore, who wish to destroy these little pests, must know both
localities of the cocoons, or they will allow one half to escape while
destroying the other.]

This insect has a flat yellow body and four pellucid wings, the two
outer ones marked with brown on the edge. In April it issues from the
pupa, which has lain under ground from the preceding September. The
female of the gooseberry saw-fly does not, like some of the family,
cut a groove in the branch to deposit her eggs;--"of what use, then,"
asks Reaumur, "is her ovipositor-saw?" In order to satisfy himself on
this point, he introduced a pair of the flies under a bell-glass along
with a branch bent from a red-currant bush, that he might watch the
process. The female immediately perambulated the leaves in search of
a place suited to her purpose, and passing under a leaf began to lay,
depositing six eggs within a quarter of an hour. Each time she placed
herself as if she wished to cut into the leaf with her saw; but, upon
taking out the leaf, the eggs appeared rather projecting than lodged
in its substance. The caterpillars are hatched in two or three weeks;
and they feed in company till after midsummer, frequently stripping
both the leaves and fruit of an extensive plantation. The caterpillar
has six legs and sixteen pro-legs, and is of a green colour mixed with
yellow, and covered with minute black dots raised like shagreen. In
its last skin it loses the black dots and becomes smooth and yellowish
white. The Caledonian Horticultural Society have published a number of
plans for destroying these caterpillars.

[Another remarkable mode of disposing of the pupa is shown in the
accompanying illustration; it represents the nest of an exotic saw-fly,
named _Deilocenes Ellisii_. In this instance, the numerous larvae unite
in spinning for themselves a common envelope of considerable strength;
it is seen as it appears when attached to the branch of a tree. The
material of which it is composed is the tough silken fibre spun by
the larvae of so many insects, which may be seen in perfection in the
cocoons of the Microgaster. Two species of this curious group will be
described in a future page.

By the side of the branch is seen a diagram of the same nest, as it
would appear in section. The irregularly angular cells are seen in the
centre, and around them is the common envelope composed of fibres.
As may be seen from the upper figure, as soon as the insects have
attained their perfect form, they gnaw their way out of the cell and
the covering also. The insect is shown as it appears when flying.

[Illustration]

We will conclude this chapter by a few remarks upon some exotic
insects, whose nests are not only remarkable in their form, but are
valuable to the entomologist in affording grounds for the reception
or rejection of certain familiar theories upon the subject of
this volume--Insect Architecture. Several of these nests are of
comparatively late discovery, and are therefore found in this work.

The curious series of cells shown in the left-hand figure is made by a
hymenopterous insect belonging to the genus Icaria, and the specimens
from which the drawing was taken may be seen in the British Museum.
They are made of a paper-like substance, much resembling in look the
material of which the common wasp builds its cells, but as they are
exposed to the air, they are necessarily tougher and stronger than
ordinary wasp cells, which are shielded from the elements. The insects
belonging to this genus make nests of very diverse forms, some of which
are stuck on leaves in a most curious manner, reminding the observer
of the parasitic mollercoids that cover the stems and fronds of large
seaweeds. Others, however, are not dependent upon leaves for their
support, but stand out boldly from the branches to which they are
fixed, supported entirely by a footstalk composed of the same material
as the cells, though necessarily of a harder and more compact substance.

[Illustration]

As many of these nests have been found in India, it is easy to trace
the manner in which they were made. The mother insect began by kneading
woody fibre into a paste, and making the footstalk of the future
nest. One end of this footstalk is attached very strongly to the
branch, and to the other end is fastened the first cell. As soon as the
Icaria has made the first beginning of the cell, and raised--or rather
lowered--the walls to a fourth or so of their complete dimensions, she
inserts an egg into the yet imperfect cell, and adds to the walls while
the egg is being hatched. Her next duty is, to add a second cell, and
this is quickly followed by a third, all these cells being fastened to
each other on three or four of their sides, leaving the others free and
unattached. It is evident that by this mode of construction the cells
nearest the branch must be the longest, because they are begun the
soonest, and this will always be found to be the case.

Now, there is a point respecting which the attention of the reader must
be specially solicited. On looking at the cells, he will see that they
are partly cylindrical and partly angular, and may perhaps think that
this fact goes towards proving that the hexagonal shape of bee cells is
owing to mutual pressure, the outer sides of the cells being rounded,
while the inner are angular. But, there are other cells in existence,
built by allied insects, and formed in an analogous manner, and which
are either angular or cylindrical, exactly according to the instinctive
powers of the insect which built them.

On the right hand of the Icarian nest may be seen a singular-looking
structure pendent at the end of a long footstalk. This is the nest of
an insect called _Mischocyttarus labiatus_, one of the Polistidae. In
this case, the cells are built so as to be defended from the rain by a
sort of penthouse, over which all the rain-drops would run, and so fall
harmless to the ground. The cells of this insect are soft in texture,
and are more cylindrical than angular, the angles being but very
slightly marked.

Here, however, is the nest of an insect called _Raphigaster
Guiniensis_, which is built in a manner similar to that of the Icaria,
the cells being closely in contact with each other. The material of
which they are made is peculiarly soft. something like very thin and
flimsy grey paper. Consequently, they must press strongly upon each
other, and we might reasonably expect to find that their angles are
well and boldly developed. But, instead of that, we find that they have
no angles at all, but remain smooth and rounded throughout their length.

[Illustration]

Perhaps the most powerful argument against the equal pressure theory is
to be found in the nest of a species of Icaria, which is shown in the
accompanying illustration.

[Illustration]

As may be seen by reference to the illustration, the material of which
they are made is so soft, that they bend over by their own weight, and
therefore we might expect to find that they would follow the shape of
the Raphigaster and the Mischocyttarus. But, we find that all the
cells are boldly angular, and that the angles are just as sharp on the
exterior of each cell as on the sides which cement the cells together.
It is clear that the bold lines and decided angles of these cells
cannot have been produced mechanically, and that they must have been
intentionally formed by the insect architect.

One single cell, such as is here shown, is sufficient to overthrow
the theory of "equal pressure," by which insects were deprived of
all mechanical skill, and supposed to labour like so many animated
machines, without caring or knowing anything about the work on which
they were engaged. According to the equal pressure theory, each of
these cells would have required six similar cells around it before it
could have assumed the hexagonal form, and yet we find that a cell
which is only connected with its neighbour by one side, has its other
five sides angular, and with the angles boldly defined.]




_CHAPTER VIII._

LEAF-ROLLING CATERPILLARS.


The labours of those insect-architects, which we have endeavoured to
describe in the preceding pages, have been chiefly those of mothers to
form a secure nest for their eggs, and the young hatched from them,
during the first stage of their existence. But a much more numerous
and not less ingenious class of architects may be found among the
newly-hatched insects themselves, who, untaught by experience, and
altogether unassisted by previous example, manifest the most marvellous
skill in the construction of tents, houses, galleries, covert-ways,
fortifications, and even cities, not to speak of subterranean caverns
and subaqueous apartments, which no human art could rival.

The caterpillars, which are familiarly termed leaf-rollers, are perfect
hermits. Each lives in a cell, which it begins to construct almost
immediately after it is hatched; and the little structure is at once
a house which protects the caterpillar from its enemies, and a store
of food for its subsistence, while it remains shut up in its prison.
But the insect only devours the inner folds. The art which these
caterpillars exercise, although called into action but once, perhaps,
in their lives, is perfect. They accomplish their purpose with a
mechanical skill, which is remarkable for its simplicity and unerring
success. The art of rolling leaves into a secure and immovable cell
may not appear very difficult: nor would it be so if the caterpillars
had fingers, or any parts which were equivalent to those delicate and
admirable natural instruments with which man accomplishes his most
elaborate works. And yet the human fingers could not roll a rocket-case
of paper more regularly than the caterpillar rolls his house of leaves.
A leaf is not a very easy substance to roll. In some trees it is very
brittle. It has also a natural elasticity,--a disposition to spring
back if it be bent,--which is caused by the continuity of its threads,
or nervures. This elasticity is speedily overcome by the ingenuity
with which the caterpillar works; and the leaf is thus retained in its
artificial position for many weeks, under every variety of temperature.
We will examine, in detail, how these little leaf-rollers accomplish
their task.

One of the most common as well as the most simple fabrics constructed
by caterpillars, may be discovered during summer on almost every kind
of bush and tree. We shall take as examples those which are found on
the lilac and on the oak.

[Illustration: Lilac-tree Moth. (_Lozotaenia riteana_, Stephens?)]

[Illustration: Nest of a Lilac-leaf Roller.]

A small but very pretty chocolate- moth, abundant in every
garden, but not readily seen, from its frequently alighting on the
ground, which is so nearly of its own colour, deposits its eggs
on the leaves of the currant, the lilac, and of some other trees,
appropriating a leaf to each egg. As soon as the caterpillar is
hatched, it begins to secure itself from birds and predatory insects
by rolling up the lilac leaf into the form of a gallery, where it may
feed in safety. We have repeatedly seen one of them when just escaped
from the egg, and only a few lines long, fix several silk threads from
one edge of a leaf to the other, or from the edge to the mid-rib; then
going to the middle of the space, he shortened the threads by bending
them with his feet, and consequently pulled the edges of the leaves
into a circular form; and he retained them in that position by gluing
down each thread as he shortened it. In their younger state, those
caterpillars seldom roll more than a small portion of the leaf; but,
when farther advanced, they unite the two edges together in their whole
extent, with the exception of a small opening at one end, by which an
exit may be made in case of need.

[Illustration: Another nest of Lilac-leaf Roller.]

Another species of caterpillar, closely allied to this, rolls up the
lilac leaves in a different form, beginning at the end of a leaf, and
fixing and pulling its threads till it gets it nearly into the shape of
a scroll of parchment. To retain this form more securely, it is not
contented, like the former insect, with threads fixed on the inside of
the leaf; but has also recourse to a few cables which it weaves on the
outside.

[Illustration: Small green Oak-moth. (_Tortrix viridana._)]

[Illustration: Nests of Oak-leaf-rolling Caterpillars.]

Another species of moth, allied to the two preceding, is of a
pretty green colour, and lays its eggs upon the leaves of the oak.
This caterpillar folds them up in a similar manner, but with this
difference, that it works on the under surface of the leaf, pulling
the edge downwards and backwards, instead of forwards and upwards.
This species is very abundant, and may readily be found as soon as
the leaves expand. In June, when the perfect insect has appeared, by
beating a branch of an oak, a whole shower of these pretty green moths
may be shook into the air.

       *       *       *       *       *

Among the leaf-rolling caterpillars, there is a small dark-brown
one, with a black head and six feet, very common in gardens, on the
currant-bush, or the leaves of the rose-tree (_Lozotaenia rosana_,
Stephens). It is exceedingly destructive to the flower-buds. The eggs
are deposited in the summer, and probably also in the autumn or in
spring, in little oval or circular patches of a green colour. The grub
makes its appearance with the first opening of the leaves, of whose
structure in the half-expanded state it takes advantage to construct
its summer tent. It is not, like some of the other leaf-rollers,
contented with a single leaf, but weaves together as many as there
are in the bud where it may chance to have been hatched, binding
their discs so firmly with silk, that all the force of the ascending
sap, and the increasing growth of the leaves, cannot break through;
a farther expansion is of course prevented. The little inhabitant in
the meanwhile banquets securely on the partitions of its tent, eating
door-ways from one apartment into another, through which it can escape
in case of danger or disturbance.

The leaflets of the rose, it may be remarked, expand in nearly the same
manner as a fan, and the operations of this ingenious little insect
retain them in the form of a fan nearly shut. Sometimes, however, it is
not contented with one bundle of leaflets, but by means of its silken
cords unites all which spring from the same bud into a rain-proof
canopy, under the protection of which it can feast on the flower-bud,
and prevent it from ever blowing.

In the instance of the currant-leaves, the proceedings of the grub
are the same; but it cannot unite the plaits so smoothly as in the
case of the rose leaflets, and it requires more labour, also, as the
nervures, being stiff, demand a greater effort to bend them. When all
the exertions of the insect prove unavailing in its endeavours to
draw the edges of a leaf together, it bends them inwards as far as
it can, and weaves a close web of silk over the open space between.
This is well exemplified in one of the commonest of our leaf-rolling
caterpillars, which may be found as early as February on the leaves of
the nettle and the white archangel (_Lamium album_). It is of a light
dirty-green colour, spotted with black, and covered with a few hairs.
In its young state it confines itself to the bosom of a small leaf,
near the insertion of the leaf-stalk, partly bending the edges inwards,
and covering in the interval with a silken curtain. As this sort of
covering is not sufficient for concealment when the animal advances
in growth, it abandons the base of the leaf for the middle, where it
doubles up one side in a very secure and ingenious manner.

[Illustration: Nest of the Nettle-leaf-rolling Caterpillar.]

We have watched this little architect begin and finish his tent upon
a nettle in our study, the whole operation taking more than half an
hour. (J. R.) He began by walking over the plant in all directions,
examining the leaves severally, as if to ascertain which was best
fitted for his purpose by being pliable, and bending with the weight
of his body. Having found one to his mind, he placed himself along
the mid-rib, to the edge of which he secured himself firmly with the
pro-legs of his tail; then stretching his head to the edge of the
leaf, he fixed a series of parallel cables between it and the mid-rib,
with another series crossing these at an acute angle. The position in
which he worked was most remarkable, for he did not, as might have
been supposed, spin his cables with his face to the leaf, but throwing
himself on his back, which was turned towards the leaf, he hung with
his whole weight by his first-made cables. This, by drawing them into
the form of a curve, shortened them, and consequently pulled the edge
of the leaf down towards the mid-rib. The weight of his body was not,
however, the only power which he employed; for, using the terminal
pro-legs as a point of support, he exerted the whole muscles of his
body to shorten his threads, and pull down the edge of the leaf. When
he had drawn the threads as tight as he could, he held them till he
spun fresh ones of sufficient strength to retain the leaf in the bent
position into which he had pulled it. He then left the first series
to hang loose while he shortened the fresh-spun ones as before. This
process was continued till he had worked down about an inch and a half
of the leaf, as much as he deemed sufficient for his habitation. This
was the first part of the architecture.

By the time he had worked to the end of the fold, he had brought the
edge of the leaf to touch the mid-rib; but it was only held in this
position by a few of the last-spun threads, for all the first-spun
ones hung loose within. Apparently aware of this, the insect protruded
more than half of its body through the small aperture left at the end,
and spun several bundles of threads on the outside precisely similar
to those ropes of a tent which extend beyond the canvas, and are
pegged into the ground. Unwilling to trust the exposure of his whole
body on the outside, lest he should be seized by the first sand-wasp
(_odynerus_) or sparrow which might descry him, he now withdrew to
complete the internal portion of his dwelling, where the threads were
hanging loose and disorderly. For this purpose he turned his head
about, and proceeded precisely as he had done at the beginning of his
task, but taking care to spin his new threads so as to leave the loose
ones on the outside, and make his apartment smooth and neat. When he
again reached the opposite end, he constructed there also a similar
series of cables on the outside, and then withdrew to give some final
touches to the interior.

It is said by Kirby and Spence,[BJ] that when these leaf-rolling insects
find that the larger nervures of the leaves are so strong as to prevent
them from bending, they "weaken it by gnawing it here and there half
through." We have never observed the circumstance, though we have
witnessed the process in some hundreds of instances; and we doubt
the statement, from the careful survey which the insect makes of the
capabilities of the leaf before the operation is begun. If she found
upon examination that a leaf would not bend, she would reject it, as we
have often seen happen, and pass to another. (J. R.)

       *       *       *       *       *

A species of leaf-roller, of the most diminutive size, merits
particular mention, although it is not remarkable in colour or figure.
It is without hair, of a greenish-white, and has all the vivacity of
the other leaf-rollers. Sorrel is the plant on which it feeds; and the
manner in which it rolls a portion of the leaf is very ingenious.

[Illustration: Leaf-rolling Caterpillars of the Sorrel.]

The structure which it contrives is a sort of conical pyramid, composed
of five or six folds lapped round each other. From the position of this
little cone the caterpillar has other labours to perform, beside that
of rolling the leaf. It first cuts across the leaf, its teeth acting
as a pair of scissors; but it does not entirely detach this segment.
It rolls it up very gradually, by attaching threads of silk to the
plane surface of the leaf, as we have before seen; and then, having
cut in a different direction, sets the cone upright, by weaving other
threads, attached to the centre of the roll and the plane of the leaf,
upon which it throws the weight of its body. This, it will be readily
seen, is a somewhat complicated effort of mechanical skill. It has been
minutely described by M. Reaumur; but the preceding representation will
perhaps make the process clearer than a more detailed account.

This caterpillar, like those of which we have already spoken, devours
all the interior of the roll. It weaves, also, in the interior, a small
and thin cocoon of white silk, the tissue of which is made compact and
close. It is then transformed into a chrysalis.

[Illustration: Nests of the Hesperia malvae, with Caterpillar,
Chrysalis, and Butterflies.]

The caterpillars of two of our largest and handsomest butterflies,
the painted lady (_Cynthia cardui_, Stephens), and the admiral, or
_Alderman_ of the London fly-fanciers (_Vanessa atalanta_), are also
leaf-rollers. The first selects the leaves of the great spear-thistle,
and sometimes those of the stemless or star-thistle, which might be
supposed rather difficult to bend; but the caterpillar is four times
as large and strong as those which we have been hitherto describing. In
some seasons it is plentiful; in others it is rarely to be met with:
but the admiral is seldom scarce in any part of the country; and by
examining the leaves of nettles which appear folded edge to edge, in
July and August, the caterpillar may be readily found.

Another butterfly (_Hesperia malvae_) is met with on dry banks where
mallows grow, in May, or even earlier, and also in August, but is not
indigenous. The caterpillar, which is grey, with a black head, and
four sulphur- spots on the neck, folds around it the leaves of
the mallow, upon which it feeds. There is nothing, however, peculiarly
different in its proceedings from those above described; but the care
with which it selects and rolls up one of the smaller leaves, when it
is about to be transformed into a chrysalis, is worthy of remark; it
joins it, indeed, so completely round and round, that it has somewhat
the resemblance of an egg. Within this green cell it lies secure, till
the time arrives when it is ready to burst its cerements, and trust to
the quickness of its wings for protection against its enemies.

Among the nests of caterpillars which roll up parcels of leaves, we
know none so well contrived as those which are found upon willows and
a species of osier. The long and narrow leaves of these plants are
naturally adapted to be adjusted parallel to each other; for this is
the direction which they have at the end of each stalk, when they are
not entirely developed. One kind of small smooth caterpillar (_Tortrix
chlorana_), with sixteen feet, the under part of which is brown, and
streaked with white, fastens these leaves together, and makes them up
into parcels. There is nothing particularly striking in the mechanical
manner in which it constructs them. It does precisely what we should do
in a similar case: it winds a thread round those leaves which must be
kept together, from a little above their termination to a very short
distance from their extreme point; and as it finds the leaves almost
constantly lying near each other, it has little difficulty in bringing
them together, as is shown in the following cut, _a_.

The prettiest of these parcels are those which are made upon a kind
of osier, the borders of whose leaves sometimes form columnar bundles
before they become developed. A section of these leaves has the
appearance of filigree-work (see _b_).

[Illustration: Nest of Willow-leaf Roller.]

A caterpillar which feeds upon the willow, and whose singular attitudes
have obtained for it the trivial name of _Ziczac_, also constructs
for itself an arbour of the leaves, by drawing them together in an
ingenious manner. M. Roesel[BK] has given a tolerable representation of
this nest, and of the caterpillar. The caterpillar is found in June;
and the moth (_Notodonta ziczac_) from May to July in the following
year (see cut, p. 151).

Beside those caterpillars which live solitary in the folds of a leaf,
there are others which associate, employing their united powers to
draw the leaves of the plants they feed upon into a covering for
their common protection. Among these we may mention the caterpillar
of a small butterfly, the plantain or Glanville fritillary (_Melitea
cinxia_), which is very scarce in this country.

[Illustration: Ziczac Caterpillar and Nest.]

Although a colony of these caterpillars is not numerous, seldom
amounting to a hundred individuals, the place which they have selected
is not hard to discover. Their abode may be seen in the meadow
in form of a tuft of herbage covered with a white web, which may
readily be mistaken, at first view, for that of a spider, but closer
inspection soon corrects this notion. It is, in fact, a sort of common
tent, in which the whole brood lives, eats, and undergoes the usual
transformations. The shape of this tent, for the most part, approaches
the pyramidal, though that depends much upon the natural growth of the
herbage which composes it. The interior is divided into compartments
formed by the union of several small tents, as it were, to which others
have been from time to time added according to the necessities of the
community.

When they have devoured all the leaves, or at least those which are
most tender and succulent, they abandon their first camp, and construct
another contiguous to it under a tuft of fresh leaves. Several of these
encampments may sometimes be seen within the distance of a foot or
two, when they can find plantain (_Plantago lanceolata_) fit for their
purpose; but though they prefer this plant, they content themselves
with grass if it is not to be procured.

When they are about to cast their skins, but particularly when they
perceive the approach of winter, they construct a more durable
apartment in the interior of their principal tent. The ordinary web is
thin and semi-transparent, permitting the leaves to be seen through it;
but their winter canvas, if we may call it so, is thick, strong, and
quite opaque, forming a sort of circular hall without any partition,
where the whole community lie coiled up and huddled together.

Early in spring they issue forth in search of fresh food, and again
construct tents to protect them from cold and rain, and from the
mid-day sun.

M. Reaumur found upon trial, that it was not only the caterpillars
hatched from the eggs of the same mother which would unite in
constructing the common tent; for different broods, when put together,
worked in the same social and harmonious manner. We ourselves
ascertained, during the present summer (1829), that this principle
of sociality is not confined to the same species, nor even to the
same genus. The experiment which we tried was to confine two broods
of different species to the same branch, by placing it in a glass of
water to prevent their escape. The caterpillars which we experimented
on were several broods of the brown-tail moth (_Porthesia auriflua_)
and the lackey (_Clisiocampa neustria_). These we found to work with
as much industry and harmony in constructing the common tent as if
they had been at liberty on their native trees; and when the lackeys
encountered the brown-tails they manifested no alarm nor uneasiness,
but passed over the backs of one another, as if they had made only a
portion of the branch. In none of their operations did they seem to
be subject to any discipline, each individual appearing to work, in
perfecting the structure, from individual instinct, in the same manner
as was remarked by M. Huber in the case of the hive-bees. In making
such experiments, it is obvious that the species of caterpillars
experimented with must feed upon the same sort of plant.[BL] (J. R.)

The design of the caterpillars in rolling up the leaves is not only
to conceal themselves from birds and predatory insects, but also to
protect themselves from the cuckoo-flies, which lie in wait in every
quarter to deposit their eggs in their bodies, that their progeny may
devour them. Their mode of concealment, however, though it appear to be
cunningly contrived and skilfully executed, is not always successful,
their enemies often discovering their hiding-place. We happened to see
a remarkable instance of this last summer (1828), in the case of one of
the lilac caterpillars which had changed into a chrysalis within the
closely-folded leaf. A small ichneumon, aware it should seem of the
very spot where the chrysalis lay within this leaf, was seen boring
through it with her ovipositor, and introducing her eggs through the
punctures thus made into the body of the dormant insect. We allowed
her to lay all her eggs, about six in number, and then put the leaf
under an inverted glass. In a few days the eggs of the cuckoo-fly were
hatched, the grubs devoured the lilac chrysalis, and finally changed
into pupae in a case of yellow silk, and into perfect insects like their
parents. (J. R.)




_CHAPTER IX._

INSECTS FORMING HABITATIONS OF DETACHED LEAVES.


The habitations of the insects which we have just described consist
of growing leaves, bent, rolled, or pressed together, and fixed in
their positions by silken threads. But there are other habitations of
a similar kind, which are constructed by cutting out and detaching
a whole leaf, or a portion of a leaf. We have already seen how
dexterously the upholsterer-bees cut out small parts of leaves and
petals with their mandibles, and fit them into their cells. Some of
the caterpillars do not exhibit quite so much neatness and elegance as
the leaf-cutting bees, though their structures answer all the purposes
intended; but there are others, as we shall presently see, that far
excel the bees, at least in the delicate minutiae of their workmanship.
We shall first advert to those structures which are the most simple.

       *       *       *       *       *

Not far from Longchamps, in a road through the Bois de Boulogne,
is a large marsh, which M. Reaumur never observed to be in a dry
state even during summer. This marsh is surrounded with very lofty
oaks, and abounds with pondweed, the water-plant named by botanists
_potamogeton_. The shining leaves of this plant, which are as large as
those of the laurel or orange-tree, but thicker and more fleshy, are
spread upon the surface of the water. Having pulled up several of these
about the middle of June, M. Reaumur observed, beneath one of the first
which he examined, an elevation of an oval shape, which was formed out
of a leaf of the same plant. He carefully examined it, and discovered
that threads of silk were attached to this elevation. Breaking the
threads, he raised up one of the ends, and saw a cavity, in which a
caterpillar (_Hydrocampa potamogeta_) was lodged. An indefatigable
observer, such as M. Reaumur, would naturally follow up this discovery;
and he has accordingly given us a memoir of the pondweed tent-maker,
distinguished by his usual minute accuracy.

In order to make a new habitation, the caterpillar fastens itself on
the under side of a leaf of the _Potamogeton_. With its mandibles it
pierces some part of this leaf, and afterwards gradually gnaws a curved
line, marking the form of the piece which it wishes to detach. When the
caterpillar has cut off, as from a piece of cloth, a patch of leaf of
the size and shape suited to its purpose, it is provided with half of
the materials requisite for making a tent. It takes hold of this piece
by its mandibles, and conveys it to the situation on the under side of
its own or another leaf, whichever is found most appropriate. It is
there disposed in such a manner that the under part of the patch--the
side which was the under part of the entire leaf--is turned towards the
under part of the new leaf, so that the inner walls of the cell or tent
are always made by the under part of two portions of leaf. The leaves
of the potamogeton are a little concave on the under side; and thus the
caterpillar produces a hollow cell, though the rims are united.

The caterpillar secures the leaf in its position by threads of white
silk. It then weaves in the cavity a cocoon, which is somewhat thin,
but of very close tissue. There it shuts itself up, to appear again
only in the form of the perfect insect, and is soon transformed into a
chrysalis. In this cocoon of silk no point touches the water; whilst
the tent of leaves, lined with silk, has been constructed underneath
the water. This fact proves that the caterpillar has a particular art
by which it repels the water from between the leaves.

When the caterpillar, which has thus conveyed and disposed a patch
of leaf against another leaf, is not ready to be transformed into a
chrysalis, it applies itself to make a tent or habitation which it
may carry everywhere about with it. It begins by slightly fixing the
piece against the perfect leaf, leaving intervals all round, between
the piece and leaf, at which it may project its head. The piece which
it has fixed serves as a model for cutting out a similar piece in the
other leaf. The caterpillar puts them accurately together, except at
one end of the oval, where an opening is left for the insect to project
its head through. When the caterpillar is inclined to change its
situation, it draws itself forward by means of its scaly limbs, riveted
upon the leaf. The membraneous limbs, which are riveted against the
inner sides of the tents, oblige it to follow the anterior part of the
body, as it advances. The caterpillar, also, puts its head out of the
tent every time it desires to eat.

There is found on the common chickweed (_Stellaria media_), towards
the end of July, a middle-sized smooth green caterpillar, having three
brown spots bordered with white on the back, and six legs and ten
pro-legs, whose architecture is worthy of observation. When it is about
to go into chrysalis, towards the beginning of August, it gnaws off,
one by one, a number of the leaves and smaller twigs of the chickweed,
and adjusts them into an oval cocoon, somewhat rough and unfinished
externally, but smooth, uniform, and finely tapestried with white silk
within. Here it undergoes its transformation securely, and, when the
period of its pupa trance has expired in the following July, it makes
its exit in the form of a yellowish moth, with several brown spots
above, and a brown band on each of its four wings below. It is also
furnished with a sort of tail.

On the cypress-spurge (_Euphorbia cyparissias_), a native woodland
plant, but not of very common occurrence, may be found, towards the
end of October, a caterpillar of a middle size, sparely tufted with
hair, and striped with black, white, red, and brown. The leaves of the
plant, which are in the form of short narrow blades of grass, are made
choice of by the caterpillar to construct its cocoon, which it does
with great neatness and regularity, the end of each leaf, after it has
been detached from the plant, being fixed to the stem, and the other
leaves placed parallel, as they are successively added. The other ends
of all these are bent inwards, so as to form a uniformly rounded oblong
figure, somewhat larger at one end than at the other.

A caterpillar which builds a very similar cocoon to the last-mentioned
may be found upon a more common plant--the yellow snap-dragon or
toad-flax (_Antirrhinum linaria_)--which is to be seen in almost every
hedge. It is somewhat shaped like a leech, is of a middle size, and the
prevailing colour pearl-grey, but striped with yellow and black. It
spins up about the beginning of September, forming the outer coating of
pieces of detached leaves of the plant, and sometimes of whole leaves
placed longitudinally, the whole disposed with great symmetry and
neatness. The moth appears in the following June.

[Illustration: Cypress-Spurge Caterpillar--(_Acronycta
Euphrasiae_)--with a Cocoon, on a branch.]

It is worthy of remark, as one of the most striking instances of
instinctive foresight, that the caterpillars which build structures of
this substantial description are destined to lie much longer in their
chrysalis trance than those which spin merely a flimsy web of silk. For
the most part, indeed, the latter undergo their final transformation
in a few weeks; while the former continue entranced the larger portion
of a year, appearing in the perfect state the summer after their
architectural labours have been completed. (J. R.) This is a remarkable
example of the instinct which leads these little creatures to act as
if under the dictates of prudence, and with a perfect knowledge of the
time, be it long or short, which will elapse before the last change of
the pupa takes place. That the caterpillar, while weaving its cocoon
and preparing to assume the pupa state, exercises any reflective
faculties, or is aware of what is about to occur relative to its own
self, we cannot admit. It enters upon a work of which it has had no
previous experience, and which is performed, as far as contingencies
allow, in the same manner by every caterpillar of the same species.
Its labours, its mode of carrying them on, and the very time in which
they are to be commenced, are all pre-appointed; and an instinctive
impulse urges and guides; and with this instinct its organic endowments
are in precise harmony; nor does instinct ever impel to labours for
which an animal is not provided. "The same wisdom," says Bonnet, "which
has constructed and arranged with so much art the various organs of
animals, and has made them concur towards one determined end, has also
provided that the different operations which are the natural results
of the economy of the animal should concur towards the same end. The
creature is directed towards his object by an invisible hand; he
executes with precision, and by one effort, those works which we so
much admire; he appears to act as if he reasoned, to return to his
labour at the proper time, to change his scheme in case of need. But in
all this he only obeys the secret influence which drives him on. He is
but an instrument which cannot judge of each action, but is wound up
by that adorable Intelligence, which has traced out for every insect
its proper labours, as he has traced the orbit of each planet. When,
therefore, I see an insect working at the construction of a nest, or a
cocoon, I am impressed with respect, because it seems to me that I am
at a spectacle where the Supreme Artist is hid behind the curtain."[BM]

There is a small sort of caterpillar which may be found on old walls,
feeding upon minute mosses and lichens, the proceedings of which are
well worthy of attention. They are similar, in appearance and size, to
the caterpillar of the small cabbage-butterfly (_Pontia rapae_), and
are smooth and bluish. The material which they use in building their
cocoons is composed of the leaves and branchlets of green moss, which
they cut into suitable pieces, detaching at the same time along with
them a portion of the earth in which they grow. They arrange these upon
the walls of their building, with the moss on the outside, and the
earth on the inside, making a sort of vault of the tiny bits of green
moss turf, dug from the surface of the wall. So neatly, also, are the
several pieces joined, that the whole might well be supposed to be a
patch of moss which had grown in form of an oval tuft, a little more
elevated than the rest growing on the wall. When these caterpillars are
shut up in a box with some moss, without earth, they construct with it
cells in form of a hollow ball, very prettily plaited and interwoven.

[Illustration: Moss-Cell of small Caterpillar (_Bryophila perla?_)]

In May last (1829), we found on the walls of Greenwich Park a great
number of caterpillars, whose manners bore some resemblance to those
of the grub described by M. Reaumur. (J. R.) They were of middle size,
with a dull-orange stripe along the back; the head and sides of the
body black, and the belly greenish. Their abodes were constructed with
ingenuity and care. A caterpillar of this sort appears to choose either
a part where the mortar contains a cavity, or it digs one suited to
its design. Over the opening of the hollow in the mortar it builds
an arched wall, so as to form a chamber considerably larger than is
usual with other architect caterpillars. It selects grains of mortar,
brick, or lichen, fixing them, by means of silk, firmly into the
structure. As some of these vaulted walls were from an inch to an inch
and a half long, and about a third of an inch wide and deep, it may
be well imagined that it would require no little industry and labour
to complete the work; yet it does not demand more than a few hours
for the insect to raise it from the foundation. Like all other insect
architects, this caterpillar uses its own body for a measuring-rule,
and partly for a mould, or rather a block or centre to shape the walls
by, curving itself round and round concentrically with the arch which
it is building.

We afterwards found one of these caterpillars, which had dug a cell in
one of the softest of the bricks, covering itself on the outside with
an arched wall of brick-dust, cemented with silk. As this brick was of
a bright-red colour, we were thereby able to ascertain that there was
not a particle of lichen employed in the structure.

The neatness mentioned by Reaumur, as remarkable in his moss-building
caterpillars, is equally observable in that which we have just
described; for, on looking at the surface of the wall, it would be
impossible for a person unacquainted with those structures to detect
where they were placed, as they are usually, on the outside, level with
the adjoining brick-work; and it is only when they are opened by the
entomologist, that the little architect is perceived lying snug in his
chamber. If a portion of the wall be thus broken down, the caterpillar
immediately commences repairing the breach, by piecing in bits of
mortar and fragments of lichen, till we can scarcely distinguish the
new portion from the old.




_CHAPTER X._

CADDIS-WORMS AND CARPENTER-CATERPILLARS.


[Illustration: Leaf Nest of Caddis-Worm.]

[Illustration: Reed Nest of Caddis-Worm.]

There is a very interesting class of grubs which live under water,
where they construct for themselves moveable tents of various materials
as their habits direct them, or as the substances they require can
be conveniently procured. Among the materials used by these singular
grubs, well-known to fishermen by the name of _caddis-worms_, and
to naturalists as the _larvae_ of the four-winged flies in the order
_Trichoptera_ of Kirby and Spence, we may mention sand, stones,
shells, wood, and leaves, which are skilfully joined and strongly
cemented. One of these grubs forms a pretty case of leaves glued
together longitudinally, but leaving an aperture sufficiently large
for the inhabitant to put out its head and shoulders when it wishes
to look about for food. Another employs pieces of reed cut into
convenient lengths, or of grass, straw, wood, &c., carefully joining
and cementing each piece to its fellow as the work proceeds; and he
frequently finishes the whole by adding a broad piece longer than the
rest to shade his door-way overhead, so that he may not be seen from
above. A more laborious structure is reared by the grub of a beautiful
caddis-fly (_Phryganea_), which weaves together a group of the leaves
of aquatic plants into a roundish ball, and in the interior of this
forms a cell for its abode. The fallowing figure from Roesel will give
a more precise notion of this structure than a lengthened description.

[Illustration]

Another of these aquatic architects makes choice of the tiny shells of
young fresh-water mussels and snails (_Planorbis_), to form a moveable
grotto; and as these little shells are for the most part inhabited, he
keeps the poor animals close prisoners, and drags them without mercy
along with him. These grotto-building grubs are by no means uncommon in
ponds; and in chalk districts, such as the country about Woolwich and
Gravesend, they are very abundant.

[Illustration: Shell Nests of Caddis-Worms.]

One of the most surprising instances of their skill occurs in the
structures of which small stones are the principal material. The
problem is to make a tube about the width of the hollow of a
wheat-straw or a crow-quill, and equally smooth and uniform. Now the
materials being small stones full of angles and irregularities, the
difficulty of performing this problem will appear to be considerable,
if not insurmountable: yet the little architects, by patiently
examining their stones and turning them round on every side, never fail
to accomplish their plans. This, however, is only part of the problem,
which is complicated with another condition, and which we have not
found recorded by former observers, namely, that the under-surface
shall be flat and smooth, without any projecting angles which might
impede its progress when dragged along the bottom of the rivulet where
it resides. The selection of the stones, indeed, may be accounted for,
from this species living in streams where, but for the weight of its
house, it would to a certainty be swept away. For this purpose, it is
probable that the grub makes choice of larger stones than it might
otherwise want; and therefore also it is that we frequently find a case
composed of very small stones and sand, to which, when nearly finished,
a large stone is added by way of ballast. In other instances, when the
materials are found to possess too great specific gravity, a bit of
light wood, or a hollow straw, is added to buoy up the case.

[Illustration: Stone Nest of Caddis-Worm.]

[Illustration: Sand Nest balanced with a Stone.]

[Illustration: Nest of Caddis-Worm balanced with Straws.]

It is worthy of remark, that the cement, used in all these cases,
is superior to pozzolana[BN] in standing water, in which it is
indissoluble. The grubs themselves are also admirably adapted for their
mode of life, the portion of their bodies which is always enclosed in
the case being soft like a meal-worm, or garden-caterpillar, while
the head and shoulders, which are for the most part projected beyond
the door-way in search of food, are firm, hard, and consequently less
liable to injury than the protected portion, should it chance to be
exposed.

We have repeatedly tried experiments with the inhabitants of those
aquatic tents, to ascertain their mode of building. We have deprived
them of their little houses, and furnished them with materials for
constructing new ones, watching their proceedings from their laying the
first stone or shell of the structure. They work at the commencement
in a very clumsy manner, attaching a great number of chips to whatever
materials may be within their reach with loose threads of silk, and
many of these they never use at all in their perfect building. They
act, indeed, much like an unskilful workman trying his hand before
committing himself upon an intended work of difficult execution. Their
main intention is, however, to have abundance of materials within
reach: for after their dwelling is fairly begun, they shut themselves
up in it, and do not again protrude more than half of their body to
procure materials; and even when they have dragged a stone, a shell, or
a chip of reed within building reach, they have often to reject it as
unfit. (J. R.)

[We have here some examples of the latter kind of nest, _i. e._, those
habitations which are made of stones and shells. Beginning at the upper
left-hand figure, we find one that is made of moderately-sized stones
cemented together in a way that reminds the observer of the manner
in which a builder forms irregular stones into a wall. Next to it is
another, in which the stones are larger and narrower, and are arranged
much as some of the caddis-worms arrange pieces of stick and straw.

In the second, and on the left-hand side, is a very long and simple
tube, made of a grass stem, and balanced by three little sticks
attached to its centre. The next figure represents a number of
sand-tubes attached to each other. These are built up laboriously
of single particles of sand, and are remarkable for their peculiar
horn-like shape, the tube having the same regular curve as the horn of
an ox or antelope, and tapering gradually from the base to the top. A
somewhat similar tube, but of larger size, is shown in the right-hand
figure.

[Illustration]

Any one who wishes to see one of these creatures rebuild its house can
do so by carefully removing it from its tube, and supplying it with
fresh material. Very great care must be taken in the removal, as the
grub is easily damaged, and it holds so tightly to the tube with a pair
of pincers at the end of its body, that it must rather be coaxed than
driven out.

If desirable, they can be made to build their new houses of most
singular materials. A lady, Miss Smee, was very successful in a series
of experiments which she made with these insects, forcing them to
make tubes of different colours and patterns, by supplying them with
 sand, pieces of stained glass of various hues, gold dust, and
similar materials. Although there was scarcely any material which they
would not use, they seemed to consider a certain amount of angularity
as essential, and rejected any object, such as a bead, of which the
surface was perfectly rounded, while they would accept the same, if it
were broken or indented.

When the caddis-grub has ceased from feeding, and is about to pass into
the perfect stage, it spins over the mouth of the tube a strong silken
web. This web is made in quite a pretty pattern, and being woven with
rather wide meshes, it allows the water to flow through the tube while
it prevents any aquatic foes from penetrating and destroying the pupa.

The remaining figures of the illustration represent tubes, around which
are built a quantity of small shells. Generally, stones are mixed
with the shells; but in some cases, shells seem to be almost the only
material.]


Carpenter-Caterpillars.

Insects, though sometimes actuated by an instinct apparently blind,
unintelligent, or unknown to themselves, manifest in other instances
a remarkable adaptation of means to ends. We have it in our power
to exemplify this in a striking manner by the proceedings of the
caterpillar of a goat-moth (_Cossus ligniperda_) which we kept till it
underwent its final change.

This caterpillar, which abounds in Kent and many other parts of the
island, feeds on the wood of willows, oaks, poplars, and other trees,
in which it eats extensive galleries; but it is not contented with the
protection afforded by these galleries during the colder months of
winter, before the arrival of which it scoops out a hollow in the tree,
if it does not find one ready prepared, sufficiently large to contain
its body in a bent or somewhat coiled-up position. On sawing off a
portion of an old poplar in the winter of 1827, we found such a cell
with a caterpillar coiled up in it.

[Illustration: Caterpillar of Goat-Moth in a Willow Tree.]

[Illustration: Winter Nest of the Goat-Caterpillar.]

It had not, however, been contented with the bare walls of the retreat
which it had hewn out of the tree, for it had lined it with a fabric
as thick as coarse broadcloth, and equally warm, composed of the
raspings of the wood scooped out of the cell, united with the strong
silk which every species of caterpillar can spin. In this snug retreat
our caterpillar, if it had not been disturbed, would have spent the
winter without eating; but upon being removed into a warm room and
placed under a glass along with some pieces of wood, which it might eat
if so inclined, it was roused for a time from its dormant state, and
began to move about. It was not long, however, in constructing a new
cell for itself, no less ingenious than the former. It either could not
gnaw into the fir plank, where it was now placed with a glass above it,
or it did not choose to do so; for it left it untouched, and made it
the basis of the edifice it began to construct. It formed, in fact, a
covering for itself precisely like the one from which we had dislodged
it,--composed of raspings of wood detached for the purpose from what
had been given it as food, the largest piece of which was employed as
a substantial covering and protection for the whole. It remained in
this retreat, motionless, and without food, till revived by the warmth
of the ensuing spring, when it gnawed its way out, and began to eat
voraciously, to make up for its long fast.

[Illustration: Nest of Goat-Moth.--Figured from specimen, and raised to
show the Pupa.]

These caterpillars are three years in arriving at their final change
into the winged state; but as the one just mentioned was nearly full
grown, it began, in the month of May, to prepare a cell, in which it
might undergo its metamorphosis. Whether it had actually improved its
skill in architecture by its previous experience we will not undertake
to say, but its second cell was greatly superior to the first. In the
first there was only one large piece of wood employed; in the second,
two pieces were placed in such a manner as to support each other, and
beneath the angle thus formed an oblong structure was made, composed,
as before, of wood-raspings and silk, but much stronger in texture than
the winter cell. In a few weeks (four, if we recollect aright) the moth
came forth. (J. R.)

[I have now before me a series of three cocoons, made by one
caterpillar of the goat-moth, showing its increase in size during the
three years that it remained in the larval state. They were found in
an old willow tree, and occupied different parts of the same burrow.
The ravages which a goat-moth caterpillar can make in a tree are almost
incredible to those who have not seen the long and tortuous burrows
which the insect will construct, burrows which at first are small and
insignificant, but which afterwards become large enough to admit a
man's finger.

Sometimes the tunnel runs just under the bark, and sometimes it goes
straight towards the centre of the tree; and no small labour is
required before it can be fully traced. Still, the result is worth
the labour, for it is most interesting to trace the creature through
its whole existence, from the tiny hole which it made soon after its
exit from the egg, to the large aperture through which it emerged as a
moth. The whole of the tunnel is strongly imbued with the peculiar and
unpleasant odour which has given to the goat-moth its popular name; and
the scent is so persistent, that it adheres to the fingers which have
touched the sides of the tunnel, and can scarcely be removed even by
repeated washings.

The moth itself is a well-known insect, though rarely seen except by
night. It is large, brown, round bodied; the wings are covered with a
soft and downy clothing, which strongly reminds the observer of the
plumage of an owl.]

A wood-boring caterpillar, of a species of moth much rarer than the
preceding (_AEgeria asiliformis_, Stephens), exhibits great ingenuity in
constructing a cell for its metamorphosis. We observed above a dozen
of them during this summer (1829) in the trunk of a poplar, one side
of which had been stripped of its bark. It was this portion of the
trunk which all the caterpillars selected for their final retreat,
not one having been observed where the tree was covered with bark. The
ingenuity of the little architect consisted in scooping its cell almost
to the very surface of the wood, leaving only an exterior covering of
unbroken wood, as thin as writing-paper. Previous, therefore, to the
chrysalis making its way through this feeble barrier, it could not
have been suspected that an insect was lodged under the smooth wood.
We observed more than one of these in the act of breaking through this
covering, within which there is, besides, a round moveable lid of a
sort of brown wax. (J. R.)

[Illustration: Larva of AEgeria.]

Another architect caterpillar, frequently to be met with in July on
the leaves of the willow and the poplar, is, in the fly-state, called
the puss-moth (_Cerura vinula_). The caterpillar is produced from
brown- shining eggs, about the size of a pin's head, which
are deposited--one, two, or more together--on the upper surface of a
leaf. In the course of six or eight weeks (during which time it casts
its skin thrice) it arrives at its full growth, when it is about as
thick, and nearly as long, as a man's thumb, and begins to prepare a
structure in which the pupa may sleep securely during the winter. As we
have, oftener than once, seen this little architect at work, from the
foundation till the completion of its edifice, we are thereby enabled
to give the details of the process.

[Illustration: Eggs of the Puss-Moth.]

[Illustration: Rudiments of the Cell of the Puss-Moth.]

The puss, it may be remarked, does not depend for protection on the
hole of a tree, or the shelter of an overhanging branch, but upon
the solidity and strength of the fabric which it rears. The material
it commonly uses is the bark of the tree upon which the cell is
constructed; but when this cannot be procured, it is contented to
employ whatever analogous materials may be within reach. One which we
had shut up in a box substituted the marble paper it was lined with for
bark, which it could not procure.[BO] With silk it first wove a thin
web round the edges of the place which it marked out for its edifice,
then it ran several threads in a spare manner from side to side, and
from end to end, but very irregularly in point of arrangement; these
were intended for the skeleton or framework of the building. When this
outline was finished, the next step was to strengthen each thread of
silk by adding several (sometimes six or eight) parallel ones, all of
which were then glued together into a single thread, by the insect
running its mandibles, charged with gluten, along the line. The meshes,
or spaces, which were thus widened by the compression of the parallel
threads, were immediately filled up with fresh threads, till at length
only very small spaces were left. It was in this stage of the operation
that the paper came into requisition, small portions of it being gnawed
off the box and glued into the meshes. It was not, however, into the
meshes only that the bits of paper were inserted; for the whole fabric
was in the end thickly studded over with them. In about half a day
from the first thread of the framework being spun the building was
completed. It was at first, however, rather soft, and yielded to slight
pressure with the finger; but as soon as it became thoroughly dry, it
was so hard that it could with difficulty be penetrated with the point
of a penknife. (J. R.)

[One puss-moth larva, which I reared, made its nest in a rather curious
manner. After it had ceased feeding it had been placed on a marble
mantelpiece under a glass tumbler, as a temporary residence until a
more appropriate dwelling could be found for it. But its instincts
urged it to make its nest without delay, and it accordingly set to
work, and spun itself up in a cocoon composed entirely of its own silk,
neither the glass tumbler or the mantelpiece affording it any material
with which to harden the walls of its dwelling.

[Illustration: Cell built by the Larva of the Puss-Moth.]

Consequently, the texture of the cocoon was of a rather singular
nature. The silken threads had been fused together so as to form a
translucent cocoon, looking as if it had been made of gelatine, and
being nearly equally transparent, the chrysalis being plainly visible
through its walls. The cocoon was thin and elastic, as if it had been
made of very thin horn; and it was so tightly fixed to the mantelpiece
as well as to the tumbler, that it could not be removed without damage.
The moth suffered no injury from the privation which the larva had to
undergo.

The cocoons of the puss-moth are to be found upon the trunks of trees,
but they are so rough, and so greatly resembling the bark, with which,
indeed, their walls are strengthened, that an inexperienced eye would
fail to detect them. Even when they have been pointed out to a novice
in practical entomology, he has failed to find them again whenever his
eye has been taken off their rugged outlines.]

A question will here suggest itself to the curious inquirer, how the
moth, which is not, like the caterpillar, furnished with mandibles
for gnawing, can find its way through so hard a wall. To resolve
this question, it is asserted by recent naturalists (see Kirby and
Spence, vol. iii. p. 15) that the moth is furnished with a peculiar
acid for dissolving itself a passage. We have a specimen of the case
of a puss-moth, in which, notwithstanding its strength, one of the
ichneumons had contrived to deposit its eggs. In the beginning of
summer, when we expected the moth to appear, and felt anxious to
observe the recorded effects of the acid, we were astonished to find a
large orange cuckoo-fly make its escape; while another, which attempted
to follow, stuck by the way and died. On detaching the cell from the
box, we found several others, which had not been able to get out, and
had died in their cocoons. (J. R.)

[Illustration: Ichneumon (_Cphion luteum_), figured from the one
mentioned.]

Among the carpenter-grubs may be mentioned that of the purple
capricorn-beetle (_Callidium violaceum_), of which the Rev. Mr. Kirby
has given an interesting account in the fifth volume of the 'Linnaean
Transactions.' This insect feeds principally on fir timber which has
been felled some time without having had the bark stripped off; but
it is often found on other wood. Though occasionally taken in this
kingdom, it is supposed not to have been originally a native. The
circumstance of this destructive little animal attacking only such
timber as had not been stripped of its bark ought to be attended to
by all persons who have any concern in this article; for the bark is
a temptation not only to this, but to various other insects; and much
of the injury done in timber might be prevented, if the trees were all
barked as soon as they were felled. The female is furnished, at the
posterior extremity of her body, with a flat retractile tube, which
she inserts between the bark and the wood, to the depth of about a
quarter of an inch, and there deposits a single egg. By stripping off
the bark, it is easy to trace the whole progress of the grub, from
the spot where it is hatched, to that where it attains its full size.
It first proceeds in a serpentine direction, filling the space which
it leaves with its excrement, resembling sawdust, and so stopping all
ingress to enemies from without. When it has arrived at its utmost
dimensions, it does not confine itself to one direction, but works in
a kind of labyrinth, eating backwards and forwards, which gives the
wood under the bark a very irregular surface: by this means its paths
are rendered of considerable width. The bed of its paths exhibits,
when closely examined, a curious appearance, occasioned by the
gnawings of its jaws, which excavate an infinity of little ramified
canals. When the insect is about to assume its chrysalis state, it
bores down obliquely into the solid wood, to the depth sometimes of
three inches, and seldom if ever less than two, forming holes nearly
semi-cylindrical, and of exactly the form of the grub which inhabits
them. At first sight one would wonder how so small and seemingly so
weak an animal could have strength to excavate so deep a mine; but when
we examine its jaws, our wonder ceases. These are large, thick, and
solid sections of a cone divided longitudinally, which, in the act of
chewing, apply to each other the whole of their interior plane surface,
so that they grind the insect's food like a pair of millstones. Some
of the grubs are hatched in October; and it is supposed that about the
beginning of March they assume their chrysalis state. At the place
in the bark opposite to the hole from whence they descended into the
wood, the perfect insects gnaw their way out, which generally takes
place betwixt the middle of May and the middle of June. These insects
are supposed only to fly in the night, but during the day they may
generally be found resting on the wood from which they were disclosed.
The grubs are destitute of feet, pale, folded, somewhat hairy, convex
above, and divided into thirteen segments. Their head is large and
convex.[BP]

[Illustration: Magnified Cells of Pyralis strigulalis?

_a._ The walls before they are joined. _b._ Walls joined, but not
closed at top. _c._ Side view of structure complete.]

It would not be easy to find a more striking example of ingenuity
than occurs in a small caterpillar which may be found in May, on the
oak, and is supposed by Kirby and Spence to be that of the _Pyralis
strigulalis_. It is of a whitish-yellow colour, tinged with a shade of
carnation, and studded with tufts of red hairs on each segment, and
two brown spots behind the head. It has fourteen feet, and the upper
part of its body is much flatter than is common in caterpillars. When
this ingenious little insect begins to form its cell, it selects a
smooth young branch of the oak, near an offgoing of the branchlets
whose angle may afford it some protection. It then measures out, with
its body for a rule, the space destined for its structure, the basement
of which is of a triangular form, with the apex at the lower end. The
building itself is composed of small, rectangular, strap-shaped pieces
of the outer bark of the branch cut out from the immediate vicinity;
the insect indeed never travels further for materials than the length
of its own body. Upon the two longest sides of the triangular base it
builds uniform walls, also of a triangular shape, and both gradually
diverging from each other as they increase in height. These are formed
with so much mathematical precision, that they fit exactly when they
are afterwards brought into contact. As soon as the little architect
has completed these walls, which resemble very much the feathers of
an arrow, it proceeds to draw them together in a manner similar to
that which the leaf-rolling caterpillars employ in constructing their
abodes, by pulling them with silken cords till they bend and converge.
Even when the two longest sides are thus joined, there is an opening
left at the upper end, which is united in a similar manner. When the
whole is finished, it requires close inspection to distinguish it from
the branch, being formed of the same materials, and having consequently
the same colour and gloss. Concealment, indeed, may be supposed,
with some justice, to be the final object of the insect in producing
this appearance, the same principle being extensively exemplified in
numerous other instances.




_CHAPTER XI._

EARTH-MASON CATERPILLARS.


Many species of caterpillars are not only skilful in concealing
themselves in their cocoons, but also in the concealment of the cocoon
itself; so that even when that is large, as in the instance of the
death's-head hawk-moth (_Acherontia atropos_), it is almost impossible
to find it. We allude to the numerous class of caterpillars which,
previous to their changing into the pupa state, bury themselves in the
earth. This circumstance would not be surprising, were it confined
to those which are but too well known in gardens, from their feeding
upon and destroying the roots of lettuce, chicory, and other plants,
as they pass a considerable portion of their lives under ground; nor
is it surprising that those which retire under ground during the
day, and come abroad to feed in the night, should form their cocoons
where they have been in the habit of concealing themselves. But it is
very singular and unexpected, that caterpillars which pass the whole
of their life on plants and even on trees, should afterwards bury
themselves in the earth. Yet, the fact is, that perhaps a greater
number make their cocoons under than above ground, particularly those
which are not clothed with hair.

Some of those caterpillars which go into the ground previous to their
change make no cocoon at all, but are contented with a rude masonry of
earth as a nest for their pupae: into the details of their operations
it will not be so necessary for us to go, as into those which exhibit
more ingenuity and care. When one of the latter is dug up it has the
appearance of nothing more than a small clod of earth, of a roundish
or oblong shape, but, generally, by no means uniform. The interior,
however, when it is laid open, always exhibits a cavity, smooth,
polished, and regular, in which the cocoon or the chrysalis lies secure
(Fig. B, p. 221). The polish of the interior is precisely such as might
be given to soft earth by moistening and kneading it with great care.
But beside this, it is usually lined with a tapestry of silk, more or
less thick, though this cannot always be discovered without the aid of
a magnifying glass. This species of caterpillars, as soon as they have
completed their growth, go into the earth, scoop out, as the cossus
does in wood, a hollow cell of an oblong form, and line it with pellets
of earth, from the size of a grain of sand to that of a pea--united, by
silk or gluten, into a fabric more or less compact, according to the
species, but all of them fitted for protecting the inhabitant, during
its winter sleep, against cold and moisture.

[Illustration: Outside view of Nests of Earth-mason Caterpillars.]

One of the examples of this occurs in the ghost-moth (_Hepialus
humuli_), which, before it retires into the earth, feeds upon the
roots of the hop or the burdock. Like other insects which construct
cells under ground, it lines the cemented earthen walls of its cell
with a smooth tapestry of silk, as closely woven as the web of the
house-spider.

Inaccurate observers have inferred that these earthen structures were
formed by a very rude and unskilful process--the caterpillar, according
to them, doing nothing more than roll itself round, while the mould
adhered to the gluey perspiration with which they describe its body
to be covered. This is a process as far from the truth as Aristotle's
account of the spider spinning its web from wool taken from its body.
Did the caterpillar do nothing more than roll itself in the earth, the
cavity would be a long tube fitted exactly to its body (Fig. c): it is
essentially different.

[Illustration: Nests, &c., of an Earth-mason Caterpillar.]

It does not indeed require very minute observation to perceive that
every grain of earth in the structure is united to the contiguous
grains by threads of silk; and that consequently, instead of the whole
having been done at once, it must have required very considerable time
and labour. This construction is rendered more obvious by throwing one
of these earthen cases into water, which dissolves the earth, but does
not act on the silk which binds it together. To understand how this is
performed, it may not be uninteresting to follow the little mason from
the beginning of his task.

When one of those burrowing caterpillars has done feeding, it enters
the earth to the depth of several inches, till it finds mould fit
for its purpose. Having nowhere to throw the earth which it may dig
out, the only means in its power of forming a cavity is to press it
with its body; and, by turning round and round for this purpose, an
oblong hollow is soon made. But were it left in this state, as Reaumur
well remarks, though the vault might endure the requisite time by the
viscosity of the earth alone, were no change to take place in its
humidity, yet, as a great number are wanted to hold out for six, eight,
and ten months, they require to be substantially built; a mere lining
of silk, therefore, would not be sufficient, and it becomes necessary
to have the walls bound with silk to some thickness.

When a caterpillar cannot find earth sufficiently moist to bear
kneading into the requisite consistence, it has the means of moistening
it with a fluid which it ejects for the purpose; and as soon as it has
thus prepared a small pellet of earth, it fits it into the wall of the
vault, and secures it with silk. As the little mason, however, always
works on the _inside_ of the building, it does not, at first view,
appear in what manner it can procure materials for making one or two
additional walls on the inside of the one first built. As the process
takes place under ground, it is not easy to discover the particulars,
for the caterpillars will not work in glazed boxes. The difficulty was
completely overcome by M. Reaumur, in the instance of the caterpillar
of the water-betony moth (_Cucullia scrophulariae_, Schrank), which he
permitted to construct the greater part of its underground building,
and then dug it up and broke a portion off from the end, leaving about
a third part of the whole to be rebuilt. Those who are unacquainted
with the instinct of insects might have supposed that, being disturbed
by the demolition of its walls, it would have left off work; but
the stimulus of providing for the great change is so powerful, that
scarcely any disturbance will interrupt a caterpillar in this species
of labour.

[Illustration: Earth-mason Caterpillars' Nests, with the perfect Moth,
&c.]

The little builder accordingly was not long in recommencing its task
for the purpose of repairing the disorder, which it accomplished in
about four hours. At first it protruded its body almost entirely
beyond the breach which had been made, to reconnoitre the exterior for
building materials. Earth was put within its reach, of the same kind
as it had previously used, and it was not long in selecting a grain
adapted to its purpose, which it fitted into the wall and secured with
silk. It first enlarged the outside of the wall by the larger and
coarser grains, and then selected finer for the interior. But before it
closed the aperture, it collected a quantity of earth on the inside,
wove a pretty thick net-work tapestry of silk over the part which
remained open, and into the meshes of this, by pushing and pressing,
it thrust grains of earth, securing them with silk till the whole
was rendered opaque; and the further operations of the insect could
no longer be watched, except that it was observed to keep in motion,
finishing, no doubt, the silken tapestry of the interior of its little
chamber. When it was completed, M. Reaumur ascertained that the portion
of the structure which had been built under his eye was equally thick
and compact with the other, which had been done under ground.

The grubs of several of the numerous species of may-fly (_Ephemera_)
excavate burrows for themselves in soft earth, on the banks of rivers
and canals, under the level of the water, an operation well described
by Scopoli, Swammerdam, and Reaumur. The excavations are always
proportioned to the size of the inhabitant; and consequently, when it
is young and small, the hole is proportionally small, though, with
respect to extent, it is always at least double the length of its body.
The hole, being under the level of the river, is always filled with
water, so that the grub swims in its native element, and while it is
secure from being preyed upon by fishes, it has its own food within
easy reach. It feeds, in fact, if we may judge from its _egesta_, upon
the slime or moistened clay with which its hole is lined.

In the bank of the stream at Lee, in Kent, we had occasion to take
up an old willow stump, which, previous to its being driven into the
bank, had been perforated in numerous places by the caterpillar of the
goat-moth (_Cossus ligniperda_). From having been driven amongst the
moist clay, these perforations became filled with it, and the grubs of
the ephemerae found them very suitable for their habitation: for the
wood supplied a more secure protection than if their galleries had been
excavated in the clay. In these holes of the wood we found several
empty, and some in which were full-grown grubs. (J. R.)

The architecture of the grub of a pretty genus of beetles, known to
entomologists by the name of _Cincindela_, is peculiarly interesting.
It was first made known by the eminent French naturalists, Geoffroy,
Desmarest, and Latreille. This grub, which may be met with during
spring, and also in summer and autumn, in sandy places, is long,
cylindric, soft whitish, and furnished with six scaly brown feet.
The head is of a square form, with six or eight eyes, and very large
in proportion to the body. They have strong jaws, and on the eighth
joint of the body there are two fleshy tubercles, thickly clothed with
reddish hairs, and armed with a recurved horny spine, the whole giving
to the grub the form of the letter Z.

[Illustration: Nest of the Grubs of Ephemerae.

A, The Grub. B, Perforations in a river bank. C, One laid open to show
the parallel structure.]

[Illustration: Nests of Ephemerae in holes of Cossus.]

With their jaws and feet they dig into the earth to the depth of
eighteen inches, forming a cylindrical cavity of greater diameter
than their body, and furnished with a perpendicular entrance. In
constructing this, the grub first clears away the particles of earth
and sand by placing them on its broad trapezoidal head, and carrying
the load in this manner beyond the area of the excavation. When it gets
deeper down, it climbs gradually up to the surface with similar loads
by means of the tubercles on its back, above described. This process
is a work of considerable time and difficulty, and in carrying its
loads the insect has often to rest by the way to recover strength for
a renewed exertion. Not unfrequently, it finds the soil so ill adapted
to its operations, that it abandons the task altogether, and begins
anew in another situation. When it has succeeded in forming a complete
den, it fixes itself at the entrance by the hooks of its tubercles,
which are admirably adapted for the purpose, forming a fulcrum or
support, while the broad plate on the top of the head exactly fits the
aperture of the excavation, and is on a level with the soil. In this
position the grub remains immovable, with jaws expanded, and ready
to seize and devour every insect which may wander within its reach,
particularly the smaller beetles; and its voracity is so great, that
it does not spare even its own species. It precipitates its prey into
the excavation, and in case of danger it retires to the bottom of its
den, a circumstance which renders it not a little difficult to discover
the grub. The method adopted by the French naturalists was to introduce
a straw or pliant twig into the hole, while they dug away, by degrees
and with great care, the earth around it, and usually found the grub at
the bottom of the cell, resting in a zig-zag position like one of the
caterpillars of the geometric moths.

When it is about to undergo its transformation into a pupa, it
carefully closes the mouth of the den, and retires to the bottom in
security.

It does not appear that the grub of the genus _Cincindela_ uses the
excavation just described for the purpose of a trap or pitfall, any
further than that it can more effectually secure its prey by tumbling
them down into it; but there are other species of grubs which
construct pitfalls for the express purpose of traps. Among these is
the larva of a fly (_Rhagio vermileo_), not unlike the common flesh
maggot. The den which it constructs is in the form of a funnel, the
sides of which are composed of sand or loose earth. It forms this
pitfall of considerable depth, by throwing out the earth obliquely on
all sides; and when its trap is finished, it stretches itself along the
bottom, remaining stiff and motionless, like a piece of wood. The last
segment of the body is bent at an angle with the rest, so as to form a
strong point of support in the struggles which it must often have to
encounter with vigorous prey. The instant that an insect tumbles into
the pitfall, the grub pounces upon it, writhes itself round it like a
serpent, transfixes it with its jaws, and sucks its juices at its ease.
Should the prey by any chance escape, the grub hurls up jets of sand
and earth, with astonishing rapidity and force, and not unfrequently
succeeds in again precipitating it to the bottom of its trap.


The Ant-Lion.

The observations of the continental naturalists have made known to us a
pitfall constructed by an insect, the details of whose operations are
exceedingly curious; we refer to the grub of the ant-lion (_Myrmeleon
formicarius_), which, though marked by Dr. Turton and Mr. Stewart as
British, has not (at least of late years) been found in this country.
As it is not, however, uncommon in France and Switzerland, it is
probable it may yet be discovered in some spot hitherto unexplored, and
if so, it will well reward the search of the curious.

The ant-lion grub being of a grey colour, and having its body composed
of rings, is not unlike a wood-louse (_Oniscus_), though it is larger,
more triangular, has only six legs, and most formidable jaws, in
form of a reaping-hook, or a pair of calliper compasses. These jaws,
however, are not for masticating, but are perforated and tubular,
for the purpose of sucking the juices of ants, upon which it feeds.
Vallisnieri was therefore mistaken, as Reaumur well remarks, when he
supposed that he had discovered its mouth. Its habits require that
it should walk backwards, and this is the only species of locomotion
which it can perform. Even this sort of motion it executes very slowly;
and were it not for the ingenuity of its stratagems, it would fare
but sparingly, since its chief food consists of ants, whose activity
and swiftness of foot would otherwise render it impossible for it to
make a single capture. Nature, however, in this, as in nearly every
other case, has given a compensating power to the individual animal,
to balance its privations. The ant-lion is slow, but it is extremely
sagacious; it cannot follow its prey, but it can entrap it.

[Illustration: Grub of the Ant-Lion, magnified, with one perfect Trap,
and another begun.]

The snare which the grub of the ant-lion employs consists of a
funnel-shaped excavation formed in loose sand, at the bottom of which
it lies in wait for the ants that chance to stumble over the margin,
and cannot, from the looseness of the walls, gain a sufficient footing
to effect their escape.

By shutting up one of these grubs in a box with loose sand, it has been
repeatedly observed constructing its trap of various dimensions, from
one to nearly three inches in diameter, according to circumstances.

In the 'Magazine of Natural History,' 1838, p. 601, Mr. Westwood gives
a very interesting account of the mode in which the ant-lion proceeds
in the excavation of its pitfall, as witnessed by himself in specimens
procured in the Parc de Belle Vue, near Paris, where, at the foot of a
very high sand-bank, these pits were numerous, and of various sizes,
but none exceeded an inch and a half or two inches in diameter, and
two-thirds of an inch deep. "The ant-lions were of various sizes,
corresponding to the size of their retreats. I brought many of them
to Paris, placing several together in a box filled with sand. They,
however, destroyed one another whilst shut up in these boxes; and I
only succeeded in bringing three of them alive to England, one of
which almost immediately afterwards (on the 23rd of July) enclosed
itself in a globular cocoon of fine sand. The other two afforded me
many opportunities of observing their proceedings. They were unable to
walk forwards,--an anomalous circumstance, and not often met with in
animals furnished with well-developed legs. It is generally backwards,
working in a spiral direction, that the creature moves, pushing itself
backwards and downwards at the same time, the head being carried
horizontally, and the back much arched, so that the extremity of the
body is forced into the sand. In this manner it proceeds backwards (to
use an Hibernianism), forming little mole-hills in the sand. But it
does not appear to me that this retrograde motion has anything to do
with the actual formation of the cell, since, as soon as it has fixed
upon a spot for its retreat, it commences throwing up the sand with the
back of its head, jerking the sand either behind its back or on one or
the other side. It shuts its long jaws, forming them into a kind of
shovel, the sharp edges of which it thrusts laterally into the sand
on each side of its head, and thereby contrives to lodge a quantity
of the sand upon the head as well as the jaws. The motion is in fact
something like that of the head of a goat, especially when butting
sideways in play. In this manner it contrives to throw away the sand,
and by degrees to make a hole entirely with its head, the fore legs
not affording the slightest assistance in the operation. During this
performance the head only is exposed, the insect having previously
pushed itself beneath the surface of the sand; but when it has made the
hole sufficiently deep, it withdraws the head also, leaving only the
jaws exposed, which are spread open in a line, and laid on the sand so
as to be scarcely visible. If alarmed, the insect immediately takes a
step backwards, withdrawing the jaws; but when an insect falls into
the hole, the jaws are instinctively and instantaneously closed, and
the insect seized by the leg, wing, or body, just as it may chance to
fall within the reach of the ant-lion's jaws. If, however, the insect
be not seized, but attempts to escape, no matter in what direction, the
ant-lion immediately begins twisting its head about, and shovelling up
the sand with the greatest agility, jerking it about on each side and
backwards, but never forwards, as misrepresented in some figures, until
the hole is made so much deeper, and such a disturbance caused in the
sides of the hole, that the insect is almost sure to be brought down
to the bottom, when it is seized by the ant-lion, which immediately
endeavours to draw it beneath the sand; and if it be very boisterous,
the ant-lion beats it about, holding it firmly by the jaws until it is
too weak for further resistance. Hence, as the head of the ant-lion is
immersed in the sand, it is evident that the accounts given in popular
works of the instinct by which it throws the sand in the direction of
the escaping prey are not quite correct. The act of throwing up the
sand, when an insect has fallen into the pit and attempts to escape,
has evidently for its chief object that of making the pit deeper and
more conical, and therefore more difficult of ascent."

[Illustration: Ant-Lion's Pitfalls, in an experimenting-box.]

It is by the action of the hinder pair of its legs that the ant-lion
drags itself backwards, the other four pair being extended trailing
after it, and leaving an impression on the surface of the fine sand
over which it has passed; and when burrowing its way beneath the
surface of the sand, it proceeds by short steps backwards. A portion
of sand at each step is thrown on the head, owing to the hump-like
form of the back: this is immediately jerked away, the body at the
same time advancing another step in its backward and spiral motion.
Where it rests, a little hillock of sand is raised by the body of the
ant-lion underneath; while its jaws emerge and spread flat on the
surface. It now probably commences its pitfall, the mode of excavating
which we have given in detail. From the spiral course described by the
ant-lion in its backward progress appears to have arisen the idea of
its tracing out a circle as the outline of its pitfall--as would an
architect or engineer; but whence sprang the often-repeated statement,
that the ant-lion loads its head with sand by means of one of its legs,
that nearest the centre of the circle, we cannot conjecture. Nor do we
know how, as it works entirely buried with the exception of the head,
the ant-lion can act when it meets with a stone or other obstacle, as
M. Bonnet states he has repeatedly witnessed. He observes that if the
stone be small, it can manage to jerk it out in the same manner as the
sand; but when it is two or three times larger and heavier than its
own body, it must have recourse to other means of removal. The larger
stones it usually leaves till the last; and when it has removed all
the sand which it intends, it then proceeds to try what it can do with
the less manageable obstacles. For this purpose it crawls backwards
to the place where a stone may be, and thrusting its tail under it,
is at great pains to get it properly balanced on its back, by an
alternate motion of the rings composing its body. When it has succeeded
in adjusting the stone, it crawls up the side of the pit with great
care, and deposits its burthen on the outside of the circle. Should
the stone happen to be round, the balance can be kept only with the
greatest difficulty, as it has to travel with its load upon a <DW72>
of loose sand, which is ready to give way at every step; and often
when the insect has carried it to the very brink, it rolls off its
back and tumbles down to the bottom of the pit. This accident, so far
from discouraging the ant-lion, only stimulates it to more persevering
efforts. Bonnet observed it renew these attempts to dislodge a stone
five or six times. It is only when it finds it utterly impossible to
succeed, that it abandons the design and commences another pit in
a fresh situation. When it succeeds in getting a stone beyond the
line of its circle, it is not contented with letting it rest there;
but, to prevent it from again rolling in, it goes on to push it to a
considerable distance. We maybe pardoned for pausing before we give
full credence to these details.

The ant-lion feeds only on the blood or juice of insects; and as soon
as it has extracted these, it tosses the dry carcase out of its den.

When it is about to change into a pupa, it proceeds in nearly the
same manner as the caterpillar of the water-betony moth (_Cucullia
scrophulariae_). It first builds a case of sand, the particles of which
are secured by threads of silk, and then tapestries the whole with a
silken web. Within this it undergoes its transformation into a pupa,
and in due time it emerges in form of a four-winged fly, closely
resembling the dragon-flies (_Libellulae_), vulgarly and erroneously
called _horse-stingers_.

The instance of the ant-lion naturally leads us to consider the design
of the Author of Nature in so nicely adjusting, in all animals, the
means of destruction and of escape. As the larger quadrupeds of prey
are provided with a most ingenious machinery for preying on the weaker,
so are those furnished with the most admirable powers of evading their
destroyers.

In the economy of insects, we constantly observe that the means of
defence, not only of the individual creatures, but of their larvae
and pupae, against the attacks of other insects, and of birds, is
proportioned, in the ingenuity of their arrangements, to the weakness
of the insect employing them. Those species which multiply the quickest
have the greatest number of enemies. Bradley, an English naturalist,
has calculated that two sparrows carry, in the course of a week, above
three thousand caterpillars to the young in their nests. But though
this is, probably, much beyond the truth, it is certain that there is
a great and constant destruction of individuals going forward; and yet
the species is never destroyed. In this way a balance is kept up, by
which one portion of animated nature cannot usurp the means of life and
enjoyment which the world offers to another portion. In all matters
relating to reproduction, Nature is prodigal in her arrangements.
Insects have more stages to pass through before they attain their
perfect growth than other creatures. The continuation of the species
is, therefore, in many cases, provided for by a much larger number
of eggs being deposited than ever become fertile. How many larvae are
produced, in comparison with the number which pass into the pupa
state; and how many pupae perish before they become perfect insects!
Every garden is covered with caterpillars; and yet how few moths and
butterflies, comparatively, are seen, even in the most sunny season?
Insects which lay few eggs are, commonly, most remarkable in their
contrivances for their preservation. The dangers to which insect life
is exposed are manifold; and therefore are the contrivances for its
preservation of the most perfect kind, and invariably adapted to the
peculiar habits of each tribe. The same wisdom determines the food of
every species of insect; and thus some are found to delight in the
rose-tree, and some in the oak. Had it been otherwise, the balance of
vegetable life would not have been preserved. It is for this reason
that the contrivances which an insect employs for obtaining its
food are curious, in proportion to the natural difficulties of its
structure. The ant-lion is carnivorous, but he has not the quickness
of the spider, nor can he spread a net over a large surface, and
issue from his citadel to seize a victim which he has caught in his
out-works. He is therefore taught to dig a trap, where he sits like
the unwieldy giants of fable, waiting for some feeble one to cross
his path. How laborious and patient are his operations--how uncertain
the chances of success! Yet he never shrinks from them, because his
instinct tells him that by these contrivances alone can he preserve his
own existence, and continue that of his species.




_CHAPTER XII._

CLOTHES-MOTH AND OTHER TENT-MAKING CATERPILLARS.--LEAF AND BARK MINERS.


There are at least five different species of moths similar in manners
and economy, the caterpillars of which feed upon animal substances,
such as furs, woollen cloths, silk, leather, and, what to the
naturalist is no less vexing, upon the specimens of insects and other
animals preserved in his cabinet. The moths in question are of the
family named _Tinea_ by entomologists, such as the tapestry-moth
(_Tinea tapetzella_), the fur-moth (_Tinea pellionella_), the wool-moth
(_Tinea vestianella_), the cabinet-moth (_Tinea destructor_, Stephens),
&c.

The moths themselves are, in the winged state, small and well fitted
for making their way through the most minute hole or chink, so that it
is scarcely possible to exclude them by the closeness of a wardrobe or
a cabinet.[BQ] If they cannot effect an entrance when a drawer is out,
or a door open, they will contrive to glide through the key-hole; and
if they once get in, it is no easy matter to dislodge or destroy them,
for they are exceedingly agile, and escape out of sight in a moment.
Moufet is of opinion that the ancients possessed an effectual method of
preserving stuffs from the moth, because the robes of Servius Tullius
were preserved up to the death of Sejanus, a period of more than five
hundred years. On turning to Pliny to learn this secret, we find him
relating that stuff laid upon a coffin will be ever after safe from
moths; in the same way as a person once stung by a scorpion will never
afterwards be stung by a bee, or a wasp, or a hornet! Rhasis, again,
says that cantharides suspended in a house drive away moths; and he
adds that they will not touch anything wrapped in a lion's skin!--the
poor little insects, says Reaumur, sarcastically, being probably in
bodily fear of so terrible an animal.[BR] Such are the stories which
fill the imagination even of philosophers, till real science entirely
expels them.

The effluvium of camphor or turpentine, or fumigation by sulphur or
chlorine, may sometimes kill them, when in the winged state, but this
will have no effect upon their eggs, and seldom upon the caterpillars;
for they wrap themselves up too closely to be easily reached by any
agent except heat. This, when it can be conveniently applied, will
be certain either to dislodge or to kill them. When the effluvium of
turpentine, however, reaches the caterpillar, Bonnet says it falls into
convulsions, becomes covered with livid blotches, and dies.[BS]

The mother insect takes care to deposit her eggs on or near such
substances as she instinctively foreknows will be best adapted for the
food of the young, taking care to distribute them so that there may
be a plentiful supply and enough of room for each. We have found, for
example, some of those caterpillars feeding upon the shreds of cloth
used in training wall-fruit trees; but we never saw more than two
caterpillars on one shred. This scattering of the eggs in many places
renders the effects of the caterpillars more injurious, from their
attacking many parts of a garment or a piece of stuff at the same time.
(J. R.)

When one of the caterpillars of this family issues from the egg, its
first care is to provide itself with a domicile, which indeed seems no
less indispensable to it than food; for, like all caterpillars that
feed under cover, it will not eat while it remains unprotected. Its
mode of building is very similar to that which is employed by other
caterpillars that make use of extraneous materials. The foundation
or framework is made of silk secreted by itself, and into this it
interweaves portions of the material upon which it feeds. It is said by
Bingley, that "after having spun a fine coating of silk _immediately
around its body_, it cuts the filaments of the wool or fur close by
the thread of the cloth, or by the skin, with its teeth, which act
in the manner of scissors, into convenient lengths, and applies the
bits, one by one, with great dexterity, to the _outside_ of its silken
case."[BT] This statement, however, is erroneous, and inconsistent with
the proceedings not only of the clothes-moth, but of every caterpillar
that constructs a covering. None of these build from within outwards,
but uniformly commence with the exterior wall, and finish by lining the
interior with the finest materials. Reaumur, however, found that the
newly-hatched caterpillars lived at first in a case of silk.

We have repeatedly witnessed the proceedings of these insects from the
very foundation of their structures; and, at the moment of writing
this, we turned out one from the carcase of an "old lady moth" (_Mormo
maura_, Ochsenheim) in our cabinet, and placed it on a desk covered
with green cloth, where it might find materials for constructing
another dwelling. It wandered about for half a day before it began its
operations; but it did not, as is asserted by Bonnet, and Kirby and
Spence, "in moving from place to place, seem to be as much incommoded
by the long hairs which surround it, as we are by walking amongst high
grass," nor, "accordingly, marching scythe in hand," did it, "with its
teeth, cut out a smooth road."[BU] On contrary, it did not cut a single
hair till it selected one for the foundation of its intended structure.
This it cut very near the cloth, in order, we suppose, to have it
as long as possible; and placed it on a line with its body. It then
immediately cut another, and placing it parallel to the first, bound
both together with a few threads of its own silk. The same process
was repeated with other hairs, till the little creature had made a
fabric of some thickness, and this it went on to extend till it was
large enough to cover its body; which (as is usual with caterpillars)
it employed as a model and measure for regulating its operations. We
remarked that it made choice of longer hairs for the outside than for
the parts of the interior, which it thought necessary to strengthen by
fresh additions; but the chamber was ultimately finished by a fine and
closely-woven tapestry of silk. We could see the progress of its work
by looking into the opening at either of the ends; for at this stage
of the structure the walls are quite opaque, and the insect concealed.
It may be thus observed to turn round, by doubling itself and bringing
its head where the tail had just been; of course, the interior is left
wide enough for this purpose, and the centre, indeed, where it turns,
is always wider than the extremities. (J. R.)

[Illustration: Cases, &c., of the Clothes-Moth (_Tinea
pellionella_).--_a_. Caterpillar feeding in a case, which has been
lengthened by ovals of different colours; _b_. Case cut at the ends for
experiment; _c_. Case cut open by the insect for enlarging it; _d_,
_e_. The clothes-moths in their perfect state, when, as they cease to
eat, they do no further injury.]

When the caterpillar increases in length, it takes care to add to
the length of its house, by working in fresh hairs at either end;
and if it be shifted to stuffs of different colours, it may be made
to construct a party- tissue, like a Scotch plaid. Reaumur
cut off with scissors a portion at each end, to compel the insect to
make up the deficiency. But the caterpillar increases in thickness
as well as in length, so that, its first house becoming too narrow,
it must either enlarge it, or build a new one. It prefers the former
as less troublesome, and accomplishes its purpose "as dexterously,"
says Bonnet, "as any tailor, and sets to work precisely as we should
do, slitting the case on the two opposite sides, and then adroitly
inserting between them two pieces of the requisite size. It does not,
however, cut open the case from one end to the other at once; the
sides would separate too far asunder, and the insect be left naked. It
therefore first cuts each side about half-way down, beginning sometimes
at the centre and sometimes at the end (Fig. _c_), and then, after
having filled up the fissure, proceeds to cut the remaining half; so
that, in fact, four enlargements are made, and four separate pieces
inserted. The colour of the case is always the same as that of the
stuff from which it is taken. Thus, if its original colour be blue,
and the insect, previously to enlarging it, be put upon red cloth,
the circles at the end, and two stripes down the middle, will be
red."[BV] Reaumur found that they cut these enlargements in no precise
order, but sometimes continuously, and sometimes opposite each other,
indifferently.

The same naturalist says he never knew one leave its old dwelling
in order to build a new; though, when once ejected by force from
its house, it would never enter it again, as some other species of
caterpillars will do, but always preferred building another. We, on
the contrary, have more than once seen them leave an old habitation.
The very caterpillar, indeed, whose history we have above given, first
took up its abode in a specimen of the ghost-moth (_Hepialus humuli_),
where, finding few suitable materials for building, it had recourse to
the cork of the drawer, with the chips of which it made a structure
almost as warm as it would have done from wool. Whether it took offence
at our disturbing it one day, or whether it did not find sufficient
food in the body of the ghost-moth, we know not; but it left its cork
house, and travelled about eighteen inches, selected "the old lady,"
one of the largest insects in the drawer, and built a new apartment,
composed partly of cork as before, and partly of bits clipt out of the
moth's wings. (J. R.)

We have seen these caterpillars form their habitations of every sort
of insect, from a butterfly to a beetle; and the soft, feathery wings
of moths answer their purpose very well: but when they fall in with
such hard materials as the musk beetle (_Cerambyx moschatus_), or the
large scolopendra of the West Indies, they find some difficulty in the
building.

[Illustration: Transformations of the honeycomb-moths. _a_ _a_ _a_,
Galleries of the cell-boring caterpillar; _b_, the female; _c_, the
male moth (_Galleria alvearia_); _d_ _d_ _d_ _d_, galleries of the
wax-eating caterpillar, _e_, seen at the entrance; _f_, the same
exposed; _g_, its cocoon; _h_, the moth (_Galleria cereana_).]

When the structure is finished, the insect deems itself secure to feed
on the materials of the cloth or other animal matter within its reach,
provided it is dry and free from fat or grease, which Reaumur found it
would not touch. This may probably be the origin of the practice of
putting a bit of candle with furs, &c., to preserve them from the moth.
For building, it always selects the straightest and loosest pieces of
wool, but for food it prefers the shortest and most compact; and to
procure these it eats into the body of the stuff, rejecting the pile
or nap, which it necessarily cuts across at the origin, and permits
to fall, leaving it threadbare, as if it had been much worn. It must
have been this circumstance which induced Bonnet to fancy (as we have
already mentioned) that it cuts the hairs to make itself a smooth,
comfortable path to walk upon. It would be equally correct to say that
an ox or a sheep dislikes walking amongst long grass, and therefore
eats it down in order to clear the way.

[There is a little insect closely allied to these moths, which does a
vast amount of harm to the bee-combs. This is the honeycomb-moth, of
which there are in England two species, both belonging to the genus
Galleria. This little creature is continually trying to make its
way into the hives, and is as continually opposed by the bees, who
instinctively know their enemy. If it once slips past the guards, the
unfortunate bees are doomed to lose a considerable amount of their
stored treasures, and have sometimes been so worried that they have
been obliged to leave the hive altogether.

As soon as it can hide itself in an empty cell--an easy matter enough
for so tiny a moth, which harmonizes exactly in colour with the
bee-combs--it proceeds to lay its eggs, and, having discharged its
office, dies. The eggs soon hatch into little grubs and caterpillars
with very hard horny heads and soft bodies. As soon as they come into
the dark world of the hive, they begin to eat their way through the
combs, spinning the while a tunnel of silk, which entirely protects
them from the stings of the bees. They can traverse these tunnels with
tolerable speed, so that the bees do not know where to find their
enemies; and if perchance they should discover one of them at the mouth
of its burrow, the hard, horny head is all that is visible, and against
its polished surface the sting of the bee is useless. The rapidity
with which they drive the silken tubes through the comb is really
marvellous; and even if they get among a collection of empty bee-combs,
they make as much havoc as if they were bred in the hive from which the
combs were taken.

In the accompanying illustration are seen figures of the two species
of honey-moths, together with their tunnels. The species may be easily
distinguished by the shape of the wings, _Galleria alvearia_ having, as
seen at Figs. _b_, _c_, the ends of its wings rounded, and _Galleria
cereana_ having them squared.

Some moths, also belonging to the vast Family Tineidae, do much damage
to grain, and have also the habit of spinning silken tissues as they
eat their way through the grain. One of them is more plentiful on the
Continent than in England, but is known in this country by the name of
the mottled woollen moth (_Tinea granella_)].

The caterpillar, which is smooth and white, ties together with silk
several grains of wheat, barley, rye, or oats, weaving a gallery
between them, from which it projects its head while feeding; the
grains, as Reaumur remarks, being prevented from rolling or slipping
by the silk which unites them. He justly ridicules the absurd notion
of its filing off the outer skin of the wheat by rubbing upon it with
its body, the latter being the softer of the two, and he disproved, by
experiment, Leeuwenhoeck's assertion that it will also feed on woollen
cloth. It is from the end of May till the beginning of July that the
moths, which are of a silvery grey, spotted with brown, appear and lay
their eggs in granaries.

[Illustration: Transformations of the Grain-moths. _a_, Grain of
barley, including a caterpillar; _b_, _c_, the grain cut across,
seen to be hollowed out, and divided by a partition of silk; _d_,
the moth (_Tinea Hordei_); _e_, grains of wheat tied together by
the caterpillar; _f_, _g_, the caterpillar and moth (_Euplocamus
granella_).]

The caterpillar of another still more singular grain-moth (_Tinea
Hordei_, Kirby and Spence) proves sometimes very destructive of
granaries. The mother-moth, in May or June, lays about twenty or
more eggs on a grain of barley or wheat; and when the caterpillars
are hatched they disperse, each selecting a single grain. M. Reaumur
imagines that sanguinary wars must sometimes arise, in cases of
preoccupancy, a single grain of barley being a rich heritage for one
of these tiny insects; but he confesses he never saw such contests.
When the caterpillar has eaten its way into the interior of the grain,
it feeds on the farina, taking care not to gnaw the skin nor even to
throw out its excrements, so that except the little hole, scarcely
discernible, the grain appears quite sound. When it has eaten all the
farina, it spins itself a case of silk within the now hollow grain, and
changes to a pupa in November.


Tent-making Caterpillars.

The caterpillars of a family of small moths (_Tineidae_), which feed on
the leaves of various trees, such as the hawthorn, the elm, the oak,
and most fruit-trees, particularly the pear, form habitations which are
exceedingly ingenious and elegant. They are so very minute that they
require close inspection to discover them; and to the cursory observer,
unacquainted with their habits, they will appear more like the withered
leaf-scales of the tree, thrown off when the buds expand, than
artificial structures made by insects. It is only, indeed, by seeing
them move about upon the leaves, that we discover they are inhabited by
a living tenant, who carries them as the snail does its shell.

These tents are from a quarter of an inch to an inch in length, and
usually about the breadth of an oat-straw. That they are of the colour
of a withered leaf is not surprising; for they are actually composed of
a piece of leaf; not, however, cut out from the whole thickness, but
artfully separated from the upper layer, as a person might separate one
of the leaves of paper from a sheet of pasteboard.

The tents of this class of caterpillars, which are found on the
elm, the alder, and other trees with serrated leaves, are much in
the shape of a minute goldfish. They are convex on the back, where
the indentations of the leaf out of which they have been cut add to
the resemblance, by appearing like the dorsal fins of the fish. By
depriving one of those caterpillars common on the hawthorn of its
tents, for the sake of experiment, we put it under the necessity of
making another; for, as Pliny remarks of the clothes-moth, they will
rather die of hunger than feed unprotected. When we placed it on a
fresh hawthorn leaf, it repeatedly examined every part of it, as if
seeking for its lost tent, though, when this was put in its way, it
would not again enter it; but, after some delay, commenced a new one.
(J. R.)

[Illustration: A Caterpillar's tent upon a leaf of the elm.--_a_, _a_,
The part of the leaf from which the tent has been cut out; _b_, the
tent itself.]

For this purpose, it began to eat through one of the two outer
membranes which compose the leaf and enclose the pulp (_parenchyma_),
some of which, also, it devoured, and then thrust the hinder part
of its body into the perforation. The cavity, however, which it had
formed, being yet too small for its reception, it immediately resumed
the task of making it larger. By continuing to gnaw into the pulp
_between_ the membranes of the leaf (for it took the greatest care not
to puncture or injure the membranes themselves), it soon succeeded in
mining out a gallery rather larger than was sufficient to contain its
body. We perceived that it did not throw out as rubbish the pulp it dug
into, but devoured it as food--a circumstance not the least remarkable
in its proceedings.

As the two membranes of leaf thus deprived of the enclosed pulp
appeared white and transparent, every movement of the insect within
could be distinctly seen; and it was not a little interesting to
watch its ingenious operations while it was making its tent from the
membranes prepared as we have just described. These, as Reaumur has
remarked, are in fact to the insect like a piece of cloth in the hands
of a tailor; and no tailor could cut out a shape with more neatness
and dexterity than this little workman does. As the caterpillar is
furnished in its mandibles with an excellent pair of scissors, this
may not appear to be a difficult task; yet, when we examine the matter
more minutely, we find that the peculiar shape of the two extremities
requires different curvatures, and this, of course, renders the
operation no less complex, as Reaumur subjoins, than the shaping of
the pieces of cloth for a coat.[BW] The insect, in fact, shapes the
membranes slightly convex on one side and concave on the other, and at
one end twice as large as the other. In the instance which we observed,
beginning at the larger end, it bent them gently on each side by
pressing them with its body thrown into a curve. We have not said it
_cuts_, but _shapes_ its materials; for it must be obvious that if the
insect had cut both the membranes at this stage of its operations, the
pieces would have fallen and carried it along with them.

To obviate such an accident it proceeded to join the two edges, and
secure them firmly with silk, before it made a single incision to
detach them. When it had in this manner joined the two edges along one
of the sides, it inserted its head on the outside of the joining, first
at one end and then at the other, gnawing the fibres till that whole
side was separated. It proceeded in the same manner with the other
side, joining the edges before it cut them: and when it arrived at the
last fibre, the only remaining support of its now finished tent, it
took the precaution, before snipping it, to moor the whole to the uncut
part of the leaf by a cable of its own silk. Consequently, when it does
cut the last nervure, it is secure from falling, and can then travel
along the leaf, carrying its tent on its back, as a snail does its
shell. (J. R.)

We have just discovered (Nov. 4th, 1829) upon the nettle a tent of a
very singular appearance, in consequence of the materials of which it
is made. The caterpillar seems, indeed, to have proceeded exactly in
the same manner as those which we have described, mining first between
the two membranes of the leaf, and then uniting these and cutting
out his tent. But the tent itself looks singular from being all over
studded with the stinging bristles of the nettle, and forming a no less
formidable coat of mail to the little inhabitant than the spiny hide
of the hedgehog. In feeding it does not seem to have mined into the
leaf, but to have eaten the whole of the lower membrane, along with the
entire pulp, leaving nothing but the upper membrane untouched. (J. R.)
During the summer of 1830 we discovered a very large tent which had
been formed out of a blade of grass; and another stuck all over with
chips of leaves upon the common maple.

[Illustration: _a_, The Caterpillar occupying the space it has eaten
between the cuticles of the leaf; _b_, a portion of the upper cuticle,
cut out for the formation of the tent; _c_, the tent nearly completed;
_d_, the perfect tent, with the caterpillar protruding its head.]


Tents of Stone-Mason Caterpillars.

The caterpillar of a small moth (_Tinea_) which feeds upon the lichens
growing on walls, builds for itself a moveable tent of a very singular
kind. M. de la Voye was the first who described these insects; but
though they are frequently overlooked, from being very small, they are
by no means uncommon on old walls. Reaumur observed them regularly
for twenty years together on the terrace-wall of the Tuileries at
Paris; and they may be found in abundance in similar situations in this
country. This accurate observer refuted by experiment the notion of M.
de la Voye that the caterpillars fed upon the stones of the wall; but
he satisfied himself that they detached particles of the stone for the
purpose of building their tents or sheaths (_fourreaux_), as he calls
their dwellings. In order to watch their mode of building, Reaumur
gently ejected half-a-dozen of them from their homes, and observed
them detach grain after grain from a piece of stone, binding each
into the wall of their building with silk till the cell acquired the
requisite magnitude, the whole operation taking about twenty-four hours
of continued labour. M. de la Voye mentions small granular bodies of a
greenish colour, placed irregularly on the exterior of the structure,
which he calls eggs; but we agree with Reaumur in thinking it more
probable that they are small fragments of moss or lichen intermixed
with the stone: in fact, we have ascertained that they are so. (J. R.)

[Illustration: Lichen-Tents and Caterpillars, both of their natural
size and magnified.]

When these little architects prepare for their change into chrysalides
before becoming moths, they attach their tents securely to the stone
over which they have hitherto rambled, by spinning a strong mooring
of silk, so as not only to fill up every interstice between the main
entrance of the tent and the stone, but also weaving a close, thick
curtain of the same material, to shut up the entire aperture.

It is usual for insects which form similar structures to issue, when
they assume the winged state, from the broader end of their habitation;
but our little stone-mason proceeds in a different manner. It leaves
open the apex of the cone from the first, for the purpose of ejecting
its excrements, and latterly it enlarges this opening a little, to
allow of a free exit when it acquires wings; taking care, however, to
spin over it a canopy of silk, as a temporary protection, which it can
afterwards burst through without difficulty. The moth itself is very
much like the common clothes-moth in form, but is of a gilded-bronze
colour, and considerably smaller.

In the same locality, M. de Maupertuis found a numerous brood of small
caterpillars, which employed grains of stone, not, like the preceding,
for building feeding-tents, but for their cocoons. This caterpillar
was of a brownish-grey colour, with a white line along the back, on
each side of which were tufts of hair. The cocoons which it built were
oval, and less in size than a hazel-nut, the grains of the stone being
skilfully woven into irregular meshes of silk.

In June, 1829, we found a numerous encampment of the tent-building
caterpillars described by MM. de la Voye and Reaumur, on the brick
wall of a garden at Blackheath, Kent. (J. R.) They were so very
small, however, and so like the lichen on the wall, that had not our
attention been previously directed to their habits, we should have
considered them as portions of the wall; for not one of them was in
motion, and it was only by the neat, turbinated, conical form in which
they had constructed their habitations that we detected them. We tried
the experiment above mentioned, of ejecting one of the caterpillars
from its tent, in order to watch its proceedings when constructing
another; but probably its haste to procure shelter, or the artificial
circumstances into which it was thrown, influenced its operations, for
it did not form so good a tent as the first, the texture of the walls
being much slighter, while it was more rounded at the apex, and of
course not so elegant. Reaumur found, in all his similar experiments,
that the new structure equalled the old; but most of the trials of this
kind which we have made correspond with the inferiority which we have
here recorded. The process indeed is the same, but it seems to be done
with more hurry and less care. It may be, indeed, in some cases, that
the supply of silk necessary to unite the bits of stone, earth, or
lichen employed, is too scanty for perfecting a second structure.

We remarked a very singular circumstance in the operations of our
little architect, which seems to have escaped the minute and accurate
attention of Reaumur. When it commenced its structure, it was
indispensable to lay a foundation for the walls about to be reared;
but as the tent was to be moveable like the shell of a snail, and not
stationary, it would not have answered its end to cement the foundation
to the wall. We had foreseen this difficulty, and felt not a little
interested in discovering how it would be got over. Accordingly, upon
watching its movements with some attention, we were soon gratified
to perceive that it used its own body as the primary support of the
building. It fixed a thread of silk upon one of its right feet, warped
it over to the corresponding left foot, and upon the thread thus
stretched between the two feet it glued grains of stone and chips of
lichen, till the wall was of the required thickness. Upon this, as a
foundation, it continued to work till it had formed a small portion in
form of a parallelogram; and proceeding in a similar way, it was not
long in making a ring a very little wider than sufficient to admit its
body. It extended this ring in breadth, by working on the inside only,
narrowing the diameter by degrees, till it began to take the form of a
cone. The apex of this cone was not closed up, but left as an aperture
through which to eject its excrements.

It is worthy of remark, that one of the caterpillars which we deprived
of its tent attempted to save itself the trouble of building a new
one, by endeavouring to unhouse one of its neighbours. For this
purpose, it got upon the outside of the inhabited tent, and, sliding
its head down to the entrance, tried to make its way into the interior.
But the rightful owner did not choose to give up his premises so
easily, and fixed his tent down so firmly upon the table where we had
placed it, that the intruder was forced to abandon his attempt. The
instant, however, that the other unmoored his tent and began to move
about, the invader renewed his efforts to eject him, persevering in
the struggle for several hours, but without a chance of success. At
one time we imagined that he would have accomplished his felonious
intentions; for he bound down the apex of the tent to the table with
cables of silk. But he attempted his entrance at the wrong end. He
ought to have tried the aperture in the apex, by enlarging which a
little he would undoubtedly have made good his entrance; and as the
inhabitant could not have turned upon him for want of room, the castle
must have been surrendered. This experiment, however, was not tried,
and there was no hope for him at the main entrance.


Muff-shaped Tents.

The ingenuity of man has pressed into his service not only the wool,
the hair, and even the skins of animals, but has most extensively
searched the vegetable kingdom for the materials of his clothing.
In all this, however, he is rivalled by the tiny inhabitants of the
insect world, as we have already seen; and we are about now to give
an additional instance of the art of a species of caterpillars which
select a warmer material for their tents than even the caterpillar
of the clothes-moth. It may have been remarked by many who are not
botanists, that the seed-catkins of the willow become, as they ripen,
covered with a species of down or cotton, which, however, is too short
in the fibre to be advantageously employed in our manufactures. But the
caterpillars, to which we have alluded, find it well adapted for their
habitations.

The muff-looking tent in which we find these insects does not require
much trouble to construct; for the caterpillar does not, like the
clothes-moth caterpillar, join the willow-cotton together, fibre by
fibre--it is contented with the state in which it finds it on the seed.
Into this it burrows, lines the interior with a tapestry of silk, and
then detaches the whole from the branch where it was growing, and
carries it about with it as a protection while it is feeding.[BX]

[Illustration: _a_, Branch of the Willow, with seed-spikes covered with
cotton; _b_, Muff-tents, made of this cotton by _c_, the Caterpillar.]

An inquiring friend of Reaumur having found one of these insects
floating about in its muff-tent upon water, concluded that they feed
upon aquatic plants; but he was soon convinced that it had only been
blown down by an accident, which must frequently happen, as willows so
often hang over water. May it not be, that the buoyant materials of the
tent were intended to furnish the little inhabitant with a life-boat,
in which, when it chanced to be blown into the water, it might sail
safely ashore and regain its native tree?


Leaf-mining Caterpillars.

The process of mining between the two membranes of a leaf is carried on
to a farther extent by minute caterpillars allied to the tent-makers
above described. The tent-maker never deserts his house, except when
compelled, and therefore can only mine to about half the length of his
own body; but the miners now to be considered make the mine itself
their dwelling-place, and as they eat their way, they lengthen and
enlarge their galleries. A few of these mining caterpillars are the
progeny of small weevils (_Curculionidae_), some of two-winged flies
(_Diptera_), but the greater number are produced from a genus of minute
moth (_Oecophora_, Latr.), which, when magnified, appear to be amongst
the most splendid and brilliant of Nature's productions, vying even
with the humming-birds and diamond-beetles of the tropics in the rich
metallic colours which bespangle their wings. Well may Bonnet call them
"tiny miracles of Nature," and regret that they are not _en grand_.[BY]

There are few plants or trees whose leaves may not, at some season of
the year, be found mined by these caterpillars, the track of whose
progress appears on the upper surface in winding lines. Let us take one
of the most common of these for an example,--that of the rose-leaf,
produced by the caterpillar of Ray's golden-silver spot (_Argyromiges
Rayella_? Curtis), of which we have just gathered above a dozen
specimens from one rose-tree. (J. R.)

It may be remarked that the winding line is black, closely resembling
the tortuous course of a river on a map,--beginning like a small brook,
and gradually increasing in breadth as it proceeds. This representation
of a river exhibits, besides, a narrow white valley on each side of
it, increasing as it goes, till it terminates in a broad delta. The
valley is the portion of the inner leaf from which the caterpillar has
eaten the pulp (_parenchyma_), while the river itself has been formed
by the liquid _ejectamenta_ of the insect, the watery part becoming
evaporated. In other species of miners, however, the dung is hard and
dry, and consequently these only exhibit the valley without the river
(see p. 255).

[Illustration: Leaf of the Monthly Rose (_Rose Indica_), mined by
Caterpillars of Argyromiges?]

On looking at the back of the leaf, where the winding line begins,
we uniformly find the shell of the very minute egg from which the
caterpillar has been hatched, and hence perceive that it digs into
the leaf the moment it escapes from the egg, without wandering a
hair's-breadth from the spot; as if afraid lest the air should visit it
too roughly. The egg is, for the most part, placed upon the mid-rib of
the rose-leaf, but sometimes on one of the larger nervures. When once
it has got within the leaf, it seems to pursue no certain direction,
sometimes working to the centre, sometimes to the circumference,
sometimes to the point, and sometimes to the base, and even,
occasionally, crossing or keeping parallel to its own previous track.

The most marvellous circumstance, however, is the minuteness of its
workmanship; for though a rose-leaf is thinner than this paper, the
insect finds room to mine a tunnel to live in, and plenty of food,
without touching the two external membranes. Let any one try with
the nicest dissecting instruments to separate the two plates of a
rose-leaf, and he will find it impossible to proceed far without
tearing one or other. The caterpillar goes still further in minute
nicety; for it may be remarked, that its track can only be seen on the
upper, and not on the under surface of the leaf, proving that it eats
as it proceeds only half the thickness of the pulp, or that portion of
it which belongs to the upper membrane of the leaf.

We have found this little miner on almost every sort of rose-tree, both
wild and cultivated, including the sweet-briar, in which, the leaf
being very small, it requires nearly the whole parenchyma to feed one
caterpillar. They seem, however, to prefer the foreign monthly rose to
any of our native species, and there are few trees of this where they
may not be discovered.

[Illustration: Leaf of the Dew-berry Bramble (_Rubus caesius_), mined by
Caterpillars.]

Tunnels very analogous to the preceding may be found upon the common
bramble (_Rubus fruticosus_); and on the holly, early in spring, one
which is in form of an irregular whitish blotch. But in the former
case, the little miner seems to proceed more regularly, always, when
newly hatched, making directly for the circumference, upon or near
which also the mother-moth deposits her egg, and winding along for half
the extent of the leaf close upon the edge, following, in some cases,
the very indentations formed by the terminating nervures.

The bramble-leaf miner seems also to differ from that of the rose-leaf,
by eating the pulp both from the upper and under surface, at least the
track is equally distinct above and below; yet this may arise from the
different consistence of the leaf pulp, that in the rose being firm,
while that of the bramble is soft and puffy.

On the leaves of the common primrose (_Primula veris_), as well as
on the garden variety of it, the polyanthus, one of those mining
caterpillars may very frequently be found. It is, however, considerably
different from the preceding, for there is no black trace--no river to
the valley which it excavates: its ejectamenta, being small and solid,
are seen, when the leaf is dried, in little black points like grains
of sand. This miner also seems more partial than the preceding to the
mid-rib and its vicinity, in consequence of which its path is seldom
so tortuous, and often appears at its extremity to terminate in an
area comparatively extensive, arising from its recrossing its previous
tracks. (J. R.)

[Illustration: Leaf of the Primrose (_Primula veris_), mined by a
Caterpillar.]

Swammerdam describes a mining caterpillar which he found on the leaves
of the alder, though it did not, like those we have just described,
excavate a winding gallery; it kept upon the same spot, and formed
only an irregular area. A moth was produced from this, whose upper
wings, he says, "shone and glittered most gloriously with crescents
of gold, silver, and brown, surrounded by borders of delicate black."
Another area miner which he found on the leaves of willows, as many as
seventeen on one leaf, producing what appeared to be rusty spots, was
metamorphosed into a very minute weevil (_Curculio Rhionoc._). He says
he has been informed that, in warm climates, worms an inch long are
found in leaves, and adds, with great simplicity, "on these many fine
experiments might have been made, if the inhabitants had not laboured
under the cursed thirst of gold."[BZ]

The vine-leaf miner, when about to construct its cocoon, cuts, from
the termination of its gallery, two pieces of the membrane of the
leaf, deprived of their pulp, in a similar manner to the tent-makers
described above, uniting them and lining them with silk. This she
carries to some distance before she lays herself up to undergo her
change. Her mode of walking under her burthen is peculiar, for,
not contented with the security of a single thread of silk, she
forms, as Bonnet says, "little mountains (_monticules_) of silk,
from distance to distance, and seizing one of these with her teeth,
drags herself forward, and makes it a scaffolding from which she
can build another."[CA] Some of the miners, however, do not leave
their galleries, but undergo their transformations there, taking the
precaution to mine a cell, not in the upper, but in the under surface;
others only shift to another portion of the leaf.


Social Leaf-Miners.

The preceding descriptions apply to caterpillars who construct their
mines in solitude, there being seldom more than one on a leaf or
leaflet, unless when two mother-flies happen to lay their eggs on the
same leaf; but there are others, such as the miners of the leaves of
the henbane (_Hyoscyamus niger_), which excavate a common area in
concert--from four to eight forming a colony. These are very like
flesh-maggots, being larger than the common miners; the leaves of this
plant, from being thick and juicy, giving them space to work and plenty
to eat.

Most of the solitary leaf-miners either cannot or will not construct
a new mine, if ejected by an experimenter from the old, as we have
frequently proved; but this is not the case with the social miners of
the henbane-leaf. Bonnet ejected one of these, and watched it with his
glass till it commenced a new tunnel, which it also enlarged with great
expedition; and in order to verify the assertion of Reaumur, that they
neither endeavour nor fear to meet one another, he introduced a second.
Neither of them manifested any knowledge of the other's contiguity,
but both worked hard at the gallery, as did a third and a fourth which
he afterwards introduced; for though they seemed uneasy, they never
attacked one another, as the solitary ones often do when they meet.[CB]


Bark-mining Caterpillars.

A very different order of mining caterpillars are the progeny of
various beetles, which excavate their galleries in the soft inner bark
of trees, or between it and the young wood (_alburnum_). Some of these,
though small, commit extensive ravages, as may readily be conceived
when we are told that as many as eighty thousand are occasionally found
on one tree. In 1783 the trees thus destroyed by the printer-beetle
(_Tomicus typographus_, Latr.), so called from its tracks resembling
letters, amounted to above a million and a half in the Hartz forest. It
appears there periodically, and confines its ravages to the fir. This
insect is said to have been found in the neighbourhood of London.

On taking off the bark of decaying poplars and willows, we have
frequently met with the tracks of a miner of this order, extending
in tortuous pathways, about a quarter of an inch broad, for several
feet and even yards in length. The excavation is not circular, but a
compressed oval, and crammed throughout with a dark- substance
like sawdust--the excrement no doubt of the little miner, who is
thereby protected from the attacks of _Staphylinidae_, and other
predaceous insects from behind. But though we have found a great
number of these subcortical tracks, we have never discovered one of
the miners, though they are very probably the grubs of the pretty
musk-beetle (_Cerambyx moschatus_), which are so abundant in the
neighbourhood of the trees in question, that the very air in summer is
perfumed with their odour. (J. R.)

[Mr. Rennie is undoubtedly right in his suggestion. I have found
similar holes in old willow trees, and have traced them throughout
their varied ramifications. They contain the larvae and pupae of the
musk-beetle, some of which may be seen in the Museum at Oxford. On
these trees, which mostly grow along the banks of the Cherwell, the
perfect beetle was so abundant that it might be taken in any number,
and, as described by Mr. Rennie, the air was perfumed with its powerful
and agreeable odour. So strong is the scent of this beetle, that I have
known it adhere to gloves after the lapse of many weeks, and I have
often caught the scent when passing along the road, and merely by the
aid of the nostrils discovered the insect.

On account of the vast number of carpenter-beetles, it is impossible to
notice more than a few of them, and we will therefore select some of
the most conspicuous. One of them, belonging to the genus _Ptilinus_,
is very familiar to us as boring into wooden furniture, and producing
the effect which is popularly called "worm-eaten." Fortunately, the
little creatures can be easily ejected, and the wood rendered free of
them ever afterwards. All that is needed is to take a syringe with a
very fine aperture--an injecting syringe is the best--and by its aid
to force into the holes a solution of corrosive sublimate in spirits
of wine--say a large teaspoonful of the powdered salt to a pint of
spirits. The rapidity with which the poisoned spirit permeates the wood
is wonderful, and in a short time it may be seen oozing out of twenty
or thirty holes at once. This solution is peculiarly effective, as it
kills all the insects, destroys every egg that it touches, and renders
the wood poisonous to the grubs that happen to escape. I used to be
greatly plagued with the Ptilinus among my ethnological collection,
until I tried the corrosive sublimate, and ever since my spears, bows
and arrows, and clubs have remained intact.

Another troublesome insect is the _Scolytus destructor_, which makes
its radiating tunnels between the bark and the tree. Whole forests have
been destroyed by this voracious little beetle, the bark having been
completely detached, and the tree necessarily killed. The habits of
this beetle are well described in the following passage.]

[Illustration: Bark mined in rays by beetle-grubs.]

We have frequently observed a very remarkable instinct in the grubs
of a species of beetle (_Scolytus destructor_, Geoffroy), which lives
under the dead bark of trees. The mother insect, as is usual with
beetles, deposits her eggs in a patch or cluster in a chink or hole in
the bark; and when the brood is hatched, they begin feeding on the bark
which had formed their cradle. There is, of course, nothing wonderful
in their eating the food selected by their mother; but it appears that,
like the caterpillars of the clothes-moth, and the tent insects, they
cannot feed except under cover. They dig, therefore, long tubular
galleries between the bark and the wood; and, in order not to interfere
with the _runs_ of their brethren, they branch off from the place of
hatching like rays from the centre of a circle: though these are not
always in a right line, yet, however near they may approach to the
contiguous ones, none of them ever break into each other's premises.
We cannot but admire the remarkable instinct implanted in these grubs
by their Creator; which guides them thus in lines diverging farther
and farther as they increase in size, so that they are prevented from
interfering with the comforts of one another.

[We now come to one or two of the beetles which bore deeply into the
very wood of the trees. As a rule, the musk-beetle keeps rather towards
the exterior of the tree, but there are many that are not so cautious,
and which besides damage the tree additionally by nibbling a quantity
of chips, wherewith they strengthen their cocoons. We will first take
the two insects which are shown in the accompanying illustration.
That on the right hand is a species of weevil, or Curculio, and is
an undescribed species belonging to the genus Rhyncophorus. It is a
native of Australia. The insect and its cocoon are drawn one third less
than their real size. The colour of the beetle is warm chestnut brown,
and the bold marks on the thorax are jet black. In its larval state
it burrows into the palm-trees, and when about to assume the pupal
condition it makes the remarkable cocoon which is figured. Generally,
these wooden cocoons are made of little chips which are bitten from the
wood, and woven together with silk. This cocoon, however, is made of
long fibres, which are torn rather than bitten, and are so long that
one of them will sometimes encircle the cell three times, making an
average length of nine inches. It is tolerably compact in structure,
and the colour is pale brown.

On the left hand is an opened cocoon of an English beetle belonging to
the genus Rhagium. Like the last-mentioned insect, the Rhagium prefers
long fibres to short chips, though it does not use them of such a
length as the Rhyncophorus. The cocoon is generally made between the
bark and the wood, from the latter of which the fibres are torn. In
consequence of the mode of structure, the cocoon is pale straw colour,
while the hollow in which it rests is quite dark.

[Illustration: Cocoon of Rhagium.

Rhyncophorus and cocoon.]

All entomologists are familiar with the pretty little wasp-beetle
(_Clytus arietis_), which derives its popular name from the
wasp-like colours of its body. In the larval state it is one of the
carpenter-grubs, and may be found in posts, fir-trees, and similar
localities. In this country, although plentiful, it is not numerous
enough to do much harm; but in Ceylon, a closely-allied species is
one of the pests of the island. It is popularly known by the title
of coffee-borer, from its habit of boring into the stems of the
coffee-plant. The landowner looks with absolute horror on this pretty
but destructive insect, and would pay a heavy sum annually to any one
who would undertake to extirpate the tiny foe. Whole plantations have
been swept off by it, and up to the present time no remedy has had
more than a temporary and partial success.]

Another capricorn beetle of this family is no less destructive to bark
in its perfect state than the above are when grubs, as from its habit
of eating round a tree, it cuts the course of the returning sap, and
destroys it.

[The late Mr. Waterton once showed me a stout branch which had fallen
on his head while he was standing under a tree, the branch having been
cut completely through by the jaws of some large longicorn beetle. The
mode in which the insect had severed the branch was exactly like that
which is practised by the beaver when it cuts down a tree.

[Illustration: Capricorn Beetle (_Cerambyx Lamia amputator_) rounding
off the bark of a tree.]

The burrows and cocoons of two other species of Cerambyx are shown
in the accompanying illustration, and in both cases may be seen the
provision which is made for the exit of the beetle after it has
attained the perfect condition. The double burrow of the left is that
of _Cerambyx carcharias_, and those on the right-hand figure are the
habitations of _Cerambyx populneus_. The reader will see how these
insects cut up the wood of the branch, and can well understand the
infinite mischief which can be done to a coffee plantation by the
Clytus.

The last wood-boring beetle which will be mentioned is the stag-beetle
of our own country. In the larval state this insect resides in tree
trunks, mostly towards the roots, and therefore escapes observation
more successfully than would be the case if it inhabited a higher
portion of the tree. When full-grown, the larva is of enormous
size, and the hole which it bores is necessarily of corresponding
dimensions. In some parts of England, the larvae are popularly called
"Joe Bassetts," and are said to turn into "Pincher Bobs." The latter
title is a very appropriate one, as any one can testify who has allowed
a fine male stag-beetle to grip his finger between its jaws. As to the
Joe Bassett, it is simply a local name.]

[Illustration: _Cerambyx carcharias._]

[Illustration: _Cerambyx populneus._]




_CHAPTER XIII._

STRUCTURES OF GRASSHOPPERS, CRICKETS, AND BEETLES.


Grasshoppers, locusts, crickets, and beetles are, in many respects, no
less interesting than the insects whose architectural proceedings we
have already detailed. They do not, indeed, build any edifice for the
accommodation of themselves or their progeny; but most, if not all of
them, excavate retreats in walls or in the ground.

The house-cricket (_Acheta domestica_) is well known for its habit
of picking out the mortar of ovens and kitchen fire-places, where
it not only enjoys warmth, but can procure abundance of food. It is
usually supposed that it feeds on bread. M. Latreille says it only
eats insects, and it certainly thrives well in houses infested by
the cockroach; but we have also known it eat and destroy lamb's-wool
stockings, and other woolen stuffs, hung near a fire to dry. It is
evidently not fond of hard labour, but prefers those places where
the mortar is already loosened, or at least is new, soft, and easily
scooped out; and in this way it will dig covert ways from room to
room. In summer, crickets often make excursions from the house to the
neighbouring fields, and dwell in the crevices of rubbish, or the
cracks made in the ground by dry weather, where they chirp as merrily
as in the snuggest chimney-corner. Whether they ever dig retreats in
such circumstances we have not ascertained: though it is not improbable
they may do so for the purpose of making nests. M. Bory St. Vincent
tells us that the Spaniards are so fond of crickets that they keep them
in cages like singing birds.[CC]


The Mole-Cricket.

[Illustration: The Mole-Cricket, with a separate outline of one of its
hands.]

The insect, called, from its similarity of habits to the mole, the
mole-cricket (_Gryllotalpa vulgaris_, Latr.), is but too well known
in gardens, corn-fields, and the moist banks of rivers and ponds, in
some parts of England, such as Wiltshire and Hampshire, though it is
comparatively rare or unknown in others. It burrows in the ground,
and forms extensive galleries similar to those of the mole, though
smaller; and these may always be recognized by a slightly elevated
ridge of mould: for the insect does not throw up the earth in hillocks
like the mole, but gradually, as it digs along, in the manner of the
field-mouse. In this way it commits great ravages, in hotbeds and in
gardens, upon peas, young cabbages, and other vegetables, the roots
of which it is said to devour. It is not improbable, we think, that,
like its congener, the house-cricket, it may also prey upon underground
insects, and undermine the plants to get at them, as the mole has been
proved to do. Mr Gould, indeed, fed a mole-cricket for several months
upon ants.

The structure of the mole-cricket's arms and hands (if we may call
them so) is admirably adapted for these operations, being both very
strong, and moved by a peculiar apparatus of muscles. The breast is
formed of a thick, hard, horny substance, which is further strengthened
within by a double framework of strong gristle, in front of the
extremities of which the shoulder-blades of the arms are firmly
jointed: a structure evidently intended to prevent the breast from
being injured by the powerful action of the muscles of the arms in
digging. The arms themselves are strong and broad, and the hand is
furnished with four large sharp claws, pointed somewhat obliquely
outwards, this being the direction in which it digs, throwing the earth
on each side of its course. So strongly indeed does it throw out its
arms, that we find it can thus easily support its own weight when held
between the finger and thumb, as we have tried upon half-a-dozen of the
living insects now in our possession.

[Illustration: Nest of the Mole-Cricket.]

The nest which the female constructs for her eggs, in the beginning
of May, is well worthy of attention. The Rev. Mr. White, of Selborne,
tells us that a gardener, at a house where he was on a visit, while
mowing grass by the side of a canal, chanced to strike his scythe too
deep, and pared off a large piece of turf, laying open to view an
interesting scene of domestic economy. There was a pretty chamber dug
in the clay, of the form and about the dimensions it would have had if
moulded by an egg, the walls being neatly smoothed and polished. In
this little cell were deposited about a hundred eggs, of the size and
form of caraway comfits, and of a dull tarnished white colour. The eggs
were not very deep, but just under a little heap of fresh mould, and
within the influence of the sun's heat.[CD] The dull tarnished white
colour, however, scarcely agrees with a parcel of these eggs now before
us, which are translucent, gelatinous, and greenish.

Like the eggs and young of other insects, however, those of the
mole-cricket are exposed to depredation, and particularly to the
ravages of a black beetle which burrows in similar localities. The
mother insect, accordingly, does not think her nest secure till she has
defended it, like a fortified town, with labyrinths, intrenchments,
ramparts, and covert ways. In some part of these out-works she stations
herself as an advanced guard, and when the beetle ventures within her
circumvallations, she pounces upon him and kills him.


The Field-Cricket.

Another insect of this family, the field-cricket (_Acheta campestris_),
also forms burrows in the ground, in which it lodges all day, and comes
out chiefly about sunset to pipe its evening song. It is so very shy
and cautious, however, that it is by no means easy to discover either
the insect or its burrow. "The children in France amuse themselves with
hunting after the field-cricket; they put into its hole an ant fastened
by a long hair, and as they draw it out the cricket does not fail to
pursue it, and issue from its retreat. Pliny informs us it might be
captured in a much more expeditious and easy manner. If, for instance,
a small and slender piece of stick were to be thrust into the burrow,
the insect, he says, would immediately get upon it for the purpose of
demanding the occasion of the intrusion: whence arose the proverb,
_stultior grillo_ (more foolish than a cricket), applied to one who,
upon light grounds, provokes his enemy, and falls into the snares which
might have been laid to entrap him."[CE]

The Rev. Mr. White, who attentively studied their habits and manners,
at first made an attempt to dig them out with a spade, but without any
great success; for either the bottom of the hole was inaccessible, from
its terminating under a large stone, or else in breaking up the ground
the poor creature was inadvertently squeezed to death. Out of one thus
bruised a great number of eggs were taken, which were long and narrow,
of a yellow colour, and covered with a very tough skin. More gentle
means were then used, and these proved successful. A pliant stalk of
grass, gently insinuated into the caverns, will probe their windings to
the bottom, and bring out the inhabitant; and thus the humane inquirer
may gratify his curiosity without injuring the object of it.

When the males meet, they sometimes fight very fiercely, as Mr. White
found by some that he put into the crevices of a dry stone wall, where
he wished to have them settle. For though they seemed distressed by
being taken out of their knowledge, yet the first that got possession
of the chinks seized on all the others that were obtruded upon him with
his large row of serrated fangs. With their strong jaws, toothed like
the shears of a lobster's claws, they perforate and round their curious
regular cells, having no fore-claws to dig with, like the mole-cricket.
When taken into the hand, they never attempt to defend themselves,
though armed with such formidable weapons. Of such herbs as grow about
the mouths of their burrows they eat indiscriminately, and never in the
day-time seem to stir more than two or three inches from home. Sitting
in the entrance of their caverns, they chirp all night as well as day,
from the middle of the month of May to the middle of July. In hot
weather, when they are most vigorous, they make the hills echo; and, in
the more still hours of darkness, may be heard to a very considerable
distance. "Not many summers ago," says Mr. White, "I endeavoured to
transplant a colony of these insects to the terrace in my garden, by
boring deep holes in the sloping turf. The new inhabitants stayed some
time, and fed and sang; but they wandered away by degrees, and were
heard at a greater distance every morning; so it appears that on this
emergency they made use of their wings in attempting to return to the
spot from which they were taken."[CF] The manner in which these insects
lay their eggs is represented in the following figure, which is that of
an insect nearly allied to the crickets, though of a different genus.

[Illustration: _Acrida verrucivora_ depositing her eggs.

The usual position of the ovipositor is represented by dots.]

A more laborious task is performed by an insect by no means uncommon
in Britain, the burying beetle (_Necrophorus vespillo_), which may be
easily recognized by its longish body, of a black colour, with two
broad and irregularly indented bands of yellowish brown. A foreign
naturalist, M. Gleditsch, gives a very interesting account of its
industry. He had "often remarked that dead moles, when laid upon the
ground, especially if upon loose earth, were almost sure to disappear
in the course of two or three days, often of twelve hours. To ascertain
the cause, he placed a mole upon one of the beds in his garden. It
had vanished by the third morning; and on digging where it had been
laid, he found it buried to the depth of three inches, and under it
four beetles, which seemed to have been the agents in this singular
inhumation. Not perceiving anything particular in the mole, he buried
it again; and on examining it at the end of six days, he found it
swarming with maggots, apparently the issue of the beetles, which M.
Gleditsch now naturally concluded had buried the carcase for the food
of their future young. To determine these points more clearly, he put
four of these insects into a glass vessel, half filled with earth and
properly secured, and upon the surface of the earth two frogs. In less
than twelve hours one of the frogs was interred by two of the beetles;
the other two ran about the whole day, as if busied in measuring the
dimensions of the remaining corpse, which on the third day was also
found buried. He then introduced a dead linnet. A pair of the beetles
were soon engaged upon the bird. They began their operations by pushing
out the earth from under the body, so as to form a cavity for its
reception; and it was curious to see the efforts which the beetles
made, by dragging at the feathers of the bird from below, to pull it
into its grave. The male, having driven the female away, continued the
work alone for five hours. He lifted up the bird, changed its place,
turned it, and arranged it in the grave, and from time to time came
out of the hole, mounted upon it, and trod it under foot, and then
retired below, and pulled it down. At length, apparently wearied with
this uninterrupted labour, it came forth, and leaned its head upon
the earth beside the bird, without the smallest motion, as if to rest
itself, for a full hour, when it again crept under the earth. The next
day, in the morning, the bird was an inch and a half under ground, and
the trench remained open the whole day, the corpse seeming as if laid
out upon a bier, surrounded with a rampart of mould. In the evening it
had sunk half an inch lower, and in another day the work was completed,
and the bird covered. M. Gleditsch continued to add other small dead
animals, which were all sooner or later buried; and the result of his
experiment was, that in fifty days four beetles had interred, in the
very small space of earth allotted to them, twelve carcases, viz., four
frogs, three small birds, two fishes, one mole, and two grasshoppers,
besides the entrails of a fish, and two morsels of the lungs of an ox.
In another experiment, a single beetle buried a mole, forty times its
own bulk and weight, in two days."[CG]

In the summer of 1826, we found on Putney Heath, in Surrey, four of
these beetles, hard at work in burying a dead crow, precisely in the
manner described by M. Gleditsch. (J. R.)


Dung-Beetle.

A still more common British insect, the dorr, clock, or dung-beetle
(_Geotrupes stercorarius_), uses different materials for burying along
with its eggs. "It digs," to use the words of Kirby and Spence, "a
deep cylindrical hole, and carrying down a mass of the dung to the
bottom, in it deposits its eggs. And many of the species of the genus
_Ateuchus_ roll together wet dung into round pellets, deposit an egg
in the midst of each, and when dry push them backwards, by their hind
feet, to holes of the surprising depth of three feet, which they have
previously dug for their reception, and which are often several yards
distant. The attention of these insects to their eggs is so remarkable,
that it was observed in the earliest ages, and is mentioned by ancient
writers, but with the addition of many fables; as that they were all of
the male sex; that they became young again every year; and that they
rolled the pellets containing their eggs from sunrise to sunset every
day, for twenty-eight days, without intermission."[CH]

"We frequently notice in our evening walks," says Mr. Knapp, "the
murmuring passage, and are often stricken by the heedless flight of the
great dorr-beetle (_Geotrupes stercorarius_), clocks, as the boys call
them. But this evening my attention was called to them in particular,
by the constant passing of such a number as to constitute something
like a little stream; and I was led to search into the object of their
direct flight, as in general it is irregular and seemingly inquisitive.
I soon found that they dropped on some recent nuisance: but what powers
of perception must these creatures possess, drawn from all distances
and directions by the very little fetor which, in such a calm evening,
could be diffused around, and by what inconceivable means could odours
reach, this beetle in such a manner as to rouse so inert an insect
into action! But it is appointed one of the great scavengers of the
earth, and marvellously endowed with powers of sensation, and means of
effecting this purpose of its being. Exquisitely fabricated as it is
to receive impressions, yet probably it is not more highly gifted than
any of the other innumerable creatures that wing their way around us,
or creep about our paths, though by this one perceptible faculty, thus
'dimly seen,' it excites our wonder and surprise. How wondrous then the
whole!

"The perfect cleanliness of these creatures is a very notable
circumstance, when we consider that nearly their whole lives are
passed in burrowing in the earth, and removing nuisances; yet such is
the admirable polish of their coating and limbs, that we very seldom
find any soil adhering to them. The meloe, and some of the scarabaei,
upon first emerging from their winter's retreat, are commonly found
with earth clinging to them; but the removal of this is one of the
first operations of the creature; and all the beetle race, the chief
occupation of which is crawling about the soil, and such dirty employs,
are, notwithstanding, remarkable for the glossiness of their covering,
and freedom from defilements of any kind. But purity of vesture
seems to be a principal precept of Nature, and observable throughout
creation. Fishes, from the nature of the element in which they reside,
can contract but little impurity. Birds are unceasingly attentive to
neatness and lustration of their plumage. All the slug race, though
covered with slimy matter calculated to collect extraneous things, and
reptiles, are perfectly free from soil. The fur and hair of beasts, in
a state of liberty and health, is never filthy or sullied with dirt.
Some birds roll themselves in dust, and, occasionally, particular
beasts cover themselves with mire; but this is not from any liking or
inclination for such things, but to free themselves from annoyances, or
to prevent the bites of insects. Whether birds in preening, and beasts
in dressing themselves, be directed by any instinctive faculty, we know
not; but they evidently derive pleasure from the operation, and thus
this feeling of enjoyment, even if the sole motive, becomes to them an
essential source of comfort and of health."[CI]

The rose or green chafer (_Cetonia aurata_), which is one of our
prettiest native insects, is one of the burrowers, and, for the purpose
of depositing her eggs, digs, about the middle of June, into soft light
ground. When she is seen at this operation, with her broad and delicate
wings folded up in their shining green cases, speckled with white, it
could hardly be imagined that she had but just descended from the air,
or dropped down from some neighbouring rose.

       *       *       *       *       *

The proceedings of the Tumble-Dung Beetle of America (_Scarabaeus
pilularius_, Linn.) are described in a very interesting manner by
Catesby, in his 'Carolina.' "I have," says he, "attentively admired
their industry, and mutual assisting of each other in rolling their
globular balls from the place where they made them to that of their
interment, which is usually the distance of some yards, more or less.
This they perform breech foremost, by raising their hind parts, and
forcing along the ball with their hind feet. Two or three of them are
sometimes engaged in trundling one ball, which, from meeting with
impediments on account of the unevenness of the ground, is sometimes
deserted by them. It is, however, attempted by others with success,
unless it happens to roll into some deep hollow or chink, where they
are constrained to leave it; but they continue their work by rolling
off the next ball that comes in their way. None of them seem to know
their own balls, but an equal care for the whole appears to affect all
the community. They form these pellets while the dung remains moist,
and leave them to harden in the sun before they attempt to roll them.
In their moving of them from place to place, both they and the balls
may frequently be seen tumbling about the little eminences that are in
their way. They are not, however, easily discouraged; and, by repeating
their attempts, usually surmount the difficulties."

He further informs us that they "find out their subsistence by the
excellency of their noses, which direct them in their flight to
newly-fallen dung, on which they immediately go to work, tempering it
with a proper mixture of earth. So intent are they always upon their
employment, that, though handled or otherwise interrupted, they are not
to be deterred, but immediately, on being freed, persist in their work
without any apprehension of danger. They are said to be so exceedingly
strong and active as to move about, with the greatest ease, things that
are many times their own weight. Dr. Brichell was supping one evening
in a planter's house of North Carolina, when two of them were conveyed,
without his knowledge, under the candlesticks. A few blows were struck
on the table, and, to his great surprise, the candlesticks began to
move about, apparently without any agency; and his surprise was not
much lessened when, on taking one of them up, he discovered that it was
only a chafer that moved it."

We have often found the necklace-beetle (_Carabus monilis_) inhabiting
a chamber dug out in the earth of a garden, just sufficient to contain
its body, and carefully smoothed and polished. From the form of this
little nest, it would seem as if it were constructed, not by digging
out the earth and removing it, but chiefly by the insect pushing its
body forcibly against the walls. The beetles which we have found
nestling in this manner have been all males; and therefore it cannot be
intended for a breeding-cell; for male insects are never, we believe,
sufficiently generous to their mates to assist them in such labours.
The beetle in question appears to be partial to celery trenches (J.
R.); probably from the loose earth of which they are composed yielding,
without much difficulty, to the pressure of its body.

[Many of the subterranean larvae which are turned up by the spade or the
plough are the imperfect conditions of earth-burrowing beetles, and
many of them are among the most insidious pests of the farmer, their
ravages being all the more dangerous because they are unseen.]

The most destructive, perhaps, of the creatures usually called grubs
are the larvae of the may-bug or cockchafer (_Melolontha vulgaris_), but
too well known, particularly in the southern and midland districts of
England, as well as in Ireland, where the grub is called the Connaught
worm;[CJ] but fortunately not abundant in the north. We only once met
with the cockchafer in Scotland, at Sorn, in Ayrshire. (J. R.) Even
in the perfect state, this insect is not a little destructive to the
leaves of both forest and fruit trees. In 1823, we remember to have
observed almost all the trees about Dulwich and Camberwell defoliated
by them; and Salisbury says, the leaves of the oaks in Richmond Park
were so eaten by them, that scarcely an entire leaf was left. But it
is in their previous larva state that they are most destructive, as we
shall see by tracing their history.

The mother cockchafer, when about to lay her eggs, digs into the
earth of a meadow or corn-field to the depth of a span, and deposits
them in a cluster at the bottom of the excavation. Roesel, in order to
watch the proceedings, put some females into glasses half-filled with
earth, covered with a tuft of grass and a piece of thin muslin. In a
fortnight, he found some hundreds of eggs deposited, of an oval shape
and a pale-yellow colour. Placing the glass in a cellar, the eggs were
hatched towards autumn, and the grubs increased remarkably in size. In
the following May they fed so voraciously that they required a fresh
turf every second day; and even this proving too scanty provender, he
sowed in several garden pots a crop of peas, lentils, and salad, and
when the plants came up he put a pair of grubs in each pot; and in
this manner he fed them through the second and third years. During
this period, they cast their skins three or four times, going for this
purpose deeper into the earth, and burrowing out a hole where they
might effect their change undisturbed; and they do the same in winter,
during which they become torpid and do not eat.

[Illustration: Transformations of the Cockchafer (_Melolontha
vulgaris_). _a_, Newly-hatched larvae. _b_, larva, one year old. _c_,
the same larva at the second year of its growth. _d_, the same three
years old. _e_, section of a bank of earth, containing the chrysalis of
the fourth year. _f_, the chafer first emerging from the earth. _g_,
the perfect chafer in a sitting posture. _h_, the same flying]

When the grub changes into a pupa, in the third autumn after it is
hatched, it digs a similar burrow about a yard deep; and when kept in
a pot, and prevented from going deep enough, it shows great uneasiness
and often dies. The perfect beetle comes forth from the pupa in January
or February; but it is then as soft as it was whilst still a grub, and
does not acquire its hardness and colour for ten or twelve days, nor
does it venture above ground before May, in the fourth year from the
time of its hatching. At this time, the beetles may be observed issuing
from their holes in the evening, and dashing themselves about in the
air as if blind.

During the three summers then of their existence in the grub state,
these insects do immense injury, burrowing between the turf and the
soil, and devouring the roots of grass and other plants; so that the
turf may easily be rolled off, as if cut by a turfing spade, while the
soil underneath for an inch or more is turned into soft mould like the
bed of a garden. Mr. Anderson, of Norwich, mentions having seen a whole
field of fine flourishing grass so undermined by these grubs, that in a
few weeks it became as dry, brittle, and withered as hay.[CK] Bingley
also tells us that "about sixty years ago, a farm near Norwich was so
infested with cockchafers, that the farmer and his servants affirmed
they gathered eighty bushels of them; and the grubs had done so much
injury, that the court of the city, in compassion to the poor fellow's
misfortune, allowed him twenty-five pounds."[CL] In the year 1785, a
farmer, near Blois, in France, employed a number of children and poor
persons to destroy the cockchafers at the rate of two liards a hundred,
and in a few days they collected fourteen thousand.[CM]

"I remember," says Salisbury, "seeing in a nursery near Bagshot,
several acres of young forest trees, particularly larch, the roots of
which were completely destroyed by it, so much so that not a single
tree was left alive."[CN] We are doubtful, however, whether this was
the grub of the cockchafer, and think it more likely to have been that
of the green rose-beetle (_Cetonia aurata_), which feeds on the roots
of trees.




_CHAPTER XIV._

ARCHITECTURE OF ANTS.--MASON-ANTS.


All the species of ants are social. There are none solitary, as is
the case with bees and wasps. They are all more or less skilful in
architecture, some employing masonry, and others being carpenters,
wood-carvers, and miners. They consequently afford much that is
interesting to naturalists who observe their operations. The genuine
history of ants has only been recently investigated, first by Gould
in 1747, and subsequently by Linnaeus, De Geer, Huber, and Latreille.
Previous to that time their real industry and their imagined
foresight were held up as moral lessons, without any great accuracy
of observation; and it is probable that, even now, the mixture of
truth and error in Addison's delightful papers in the Guardian (Nos.
156, 157) may be more generally attractive than the minute relation
of careful naturalists. Gould disproved, most satisfactorily, the
ancient fable of ants storing up corn for winter provision, no species
of ants ever eating grain, or feeding in the winter upon anything. It
is to Huber the younger, however, that we are chiefly indebted for
our knowledge of the habits and economy of ants; and to Latreille for
a closer distinction of the species. Some of the more interesting
species, whose singular economy is described by the younger Huber, have
not been hitherto found in this country. We shall, however, discover
matter of very considerable interest in those which are indigenous;
and as our principal object is to excite inquiry and observation with
regard to those insects which may be easily watched in our own gardens
and fields, we shall chiefly confine ourselves to the ants of these
islands. We shall begin with the labours of those native ants which may
be called earth-masons, from their digging in the ground, and forming
structures with pellets of moistened loam, clay, or sand.


Mason-Ants.

We have used in the preceding pages the terms _mason-bees_ and
_mason-wasps_, for insects which build their nests of earthy materials.
On the same principle, we have followed the ingenious M. Huber the
younger, in employing the term mason-ants for those whose nests on the
exterior appear to be hillocks of earth, without the admixture of other
materials, whilst in the interior they present a series of labyrinths,
lodges, vaults, and galleries constructed with considerable skill. Of
these mason-ants, as of the mason-wasps and bees already described,
there are several species, differing from one another in their skill in
the art of architecture.

One of the most common of the ant-masons is the turf-ant (_Formica
caespitum_, Latr.), which is very small and of a blackish-brown colour.
Its architecture is not upon quite so extensive a scale as some of the
others; but, though slight, it is very ingenious. Sometimes they make
choice of the shelter of a flat stone or other covering, beneath which
they hollow out chambers and communicating galleries; at other times
they are contented with the open ground; but most commonly they select
a tuft of grass or other herbage, the stems of which serve for columns
to their earthen walls.

We had a small colony of these ants accidentally established in
a flower-pot, in which we were rearing some young plants of the
tiger-lily (_Lilium tigrinum_), the stems of which being stronger than
the grass where they usually build, enabled them to rear their edifice
higher, and also to make it more secure, than they otherwise might.
It was wholly formed of small grains of moist earth, piled up between
the stems of the lily without any apparent cement; indeed it has been
ascertained by Huber, as we shall afterwards see, that they use no
cement beside water. This is not always to be procured, as they depend
altogether on rains and dew; but they possess the art of joining grains
of dry sand so as to support one another, on some similar principle, no
doubt, to that of the arch.

The nest which our turf-ants constructed in the flower-pot was
externally of an imperfect square form, in consequence of its
situation; for they usually prefer a circular plan. The principal
chambers were placed under the arches, and, when inspected, contained
a pile of cocoons, and pupae. Beneath those upper chambers there were
others dug out deeper down, in which were also a numerous collection of
eggs and cocoons in various stages of advancement. (J. R.)

Mr. Knapp describes a still more curious structure of another species
of ant common in this country:--"One year," says he, "on the third of
March, my labourer being employed in cutting up ant-hills, or tumps
as we call them, exposed to view multitudes of the yellow species
(_Formica flava_) in their winter's retirement. They were collected in
numbers in little cells and compartments, communicating with others by
means of narrow passages. In many of the cells they had deposited their
larvae, which they were surrounding and attending, but not brooding over
or covering. Being disturbed by our rude operations, they removed them
from our sight to more hidden compartments. The larvae were small. Some
of these ant-hills contained multitudes of the young of the wood-louse
(_Oniscus armadillo_), inhabiting with perfect familiarity the same
compartments as the ants, crawling about with great activity with them,
and perfectly domesticated with each other. They were small and white;
but the constant vibration of their antennae, and the alacrity of their
motions, manifested a healthy vigour. The ants were in a torpid state;
but on being removed into a temperate room, they assumed much of their
summer's animation. How these creatures are supported during the winter
season it is difficult to comprehend; as in no one instance could we
perceive any store or provision made for the supply of their wants.
The minute size of the larvae manifested that they had been recently
deposited; and consequently that their parents had not remained during
winter in a dormant state, and thus free from the calls of hunger. The
preceding month of February, and part of January, had been remarkably
severe; the frost had penetrated deep into the earth, and long held it
frozen; the ants were in many cases not more than four inches beneath
the surface, and must have been enclosed in a mass of frozen soil for
a long period; yet they, their young, and the onisci, were perfectly
uninjured by it: affording another proof of the fallacy of the commonly
received opinion, that cold is _universally_ destructive to insect
life."[CO]

The earth employed by mason-ants is usually moist clay, either dug from
the interior parts of their city or moistened by rain. The mining-ants
and the ash- (_Formica fusca_) employ earth which is probably
not selected with so much care, for it forms a much coarser mortar than
what we see used in the structure of the yellow ants (_F. flava_) and
the brown ants (_F. brunnea_). We have never observed them bringing
their building materials of this kind from a distance, like the
mason-bees and like the wood or hill ant (_F. rufa_); but they take
care, before they fix upon a locality, that it shall produce them all
that they require. We are indebted to Huber the younger for the most
complete account which has hitherto been given of these operations, of
which details we shall make free use.

"To form," says this shrewd observer, "a correct judgment of the
interior arrangement or distribution of an ant-hill, it is necessary to
select such as have not been accidentally spoiled, or whose form has
not been too much altered by local circumstances; a slight attention
will then suffice to show that the habitations of the different species
are not all constructed after the same system. Thus, the hillock raised
by the ash- ants will always present thick walls, fabricated
with coarse earth, well-marked stories, and large chambers, with
vaulted ceilings, resting upon a solid base. We never observe roads, or
galleries, properly so called, but large passages, of an oval form, and
all around considerable cavities and extensive embankments of earth. We
further notice, that the little architects observe a certain proportion
between the large arched ceilings and the pillars that are to support
them.

"The brown ant (_Formica brunnea_), one of the smallest of the ants, is
particularly remarkable for the extreme finish of its work. Its body is
of a reddish shining brown, its head a little deeper, and the antennae
and feet a little lighter in colour. The abdomen is of an obscure
brown, the scale narrow, of a square form, and slightly scolloped. The
body is one line and two-fifths in length.[CP]

"This ant, one of the most industrious of its tribe, forms its nest
of stories four or five lines in height. The partitions are not more
than half a line in thickness; and the substance of which they are
composed is so finely grained, that the inner walls present one smooth
unbroken surface. These stories are not horizontal; they follow the
<DW72> of the ant-hill, and lie one upon another to the ground-floor,
which communicates with the subterranean lodges. They are not always,
however, arranged with the same regularity, for these ants do not
follow an invariable plan; it appears, on the contrary, that nature
has allowed them a certain latitude in this respect, and that they
can, according to circumstances, modify them to their wish; but
however fantastical their habitations may appear, we always observe
they have been formed by concentrical stories. On examining each
story separately, we observe a number of cavities or halls, lodges
of narrower dimensions, and long galleries, which serve for general
communication. The arched ceilings covering the most spacious places
are supported either by little columns, slender walls, or by regular
buttresses. We also notice chambers, that have but one entrance,
communicating with the lower story, and large open spaces, serving as a
kind of cross-road (_carrefour_), in which all the streets terminate.

"Such is the manner in which the habitations of these ants are
constructed. Upon opening them, we commonly find the apartments, as
well as the large open spaces, filled with adult ants; and always
observed their pupae collected in the apartments more or less near the
surface. This, however, seems regulated by the hour of the day, and
the temperature: for in this respect these ants are endowed with
great sensibility, and know the degree of heat best adapted for their
young. The ant-hill contains, sometimes, more than twenty stories
in its upper portion, and at least as many under the surface of the
ground. By this arrangement the ants are enabled, with the greatest
facility, to regulate the heat. When a too-burning sun overheats their
upper apartments, they withdraw their little ones to the bottom of
the ant-hill. The ground-floor becoming, in its turn, uninhabitable
during the rainy season, the ants of this species transport what most
interests them to the higher stories; and it is there we find them more
usually assembled, with their eggs and pupae, when the subterranean
apartments are submerged."[CQ]

Ants have a great dislike to water, when it exceeds that of a light
shower to moisten their building materials. One species, mentioned
by Azara as indigenous to South America, instinctively builds a nest
from three to six feet high,[CR] to provide against the inundations
during the rainy season. Even this, however, does not always save them
from submersion; and, when that occurs, they are compelled, in order
to prevent themselves from being swept away, to form a group somewhat
similar to the curtain of the wax-workers of hive-bees (see p. 133).
The ants constituting the basis of this group lay hold of some shrub
for security, while their companions hold on by them; and thus the
whole colony, forming an animated raft, floats on the surface of the
water till the inundation (which seldom continues longer than a day
or two) subsides. We confess, however, that we are somewhat sceptical
respecting this story, notwithstanding the very high character of the
Spanish naturalist.

It is usual with architectural insects to employ some animal secretion,
by way of mortar or size, to temper the materials with which they
work; but the whole economy of ants is so different, that it would be
wrong to infer from analogy a similarity in this respect, though the
exquisite polish and extreme delicacy of finish in their structures
lead, naturally, to such a conclusion. M. P. Huber, in order to resolve
this question, at first thought of subjecting the materials of the
walls to chemical analysis, but wisely (as we think) abandoned it for
the surer method of observation. The details which he has given, as the
result of his researches, are exceedingly curious and instructive. He
began by observing an ant-hill till he could perceive some change in
its form.

"The inhabitants," says he, "of that which I selected, kept within
during the day, or only went out by subterranean galleries which opened
at some feet distance in the meadow. There were, however, two or three
small openings on the surface of the nest; but I saw none of the
labourers pass out this way, on account of their being too much exposed
to the sun, which these insects greatly dread. This ant-hill, which
had a round form, rose in the grass, at the border of a path, and had
sustained no injury. I soon perceived that the freshness of the air and
the dew invited the ants to walk over the surface of their nest; they
began making new apertures; several ants might be seen arriving at the
same time, thrusting their heads from the entrances, moving about their
antennae, and at length adventuring forth to visit the environs.

"This brought to my recollection a singular opinion of the ancients.
They believed that ants were occupied in their architectural labours
during the night, when the moon was at its full."[CS]

M. Latreille discovered a species of ants which were, so far as he
could ascertain, completely blind,[CT] and of course it would be
immaterial to them whether they worked by night or during the day.
All observers indeed agree that ants labour in the night, and a
French naturalist is therefore of opinion that they never sleep--a
circumstance which is well ascertained with respect to other animals,
such as the shark, which will track a ship in full sail for weeks
together.[CU] The ingenious historian of English ants, Gould, says
they never intermit their labours by night or by day, except when
compelled by excessive rains. It is probable the ancients were mistaken
in asserting that they only work when the moon shines;[CV] for, like
bees, they seem to find no difficulty in building in the dark, their
subterranean apartments being as well finished as the upper stories of
their buildings. But to proceed with the narrative of M. P. Huber.

"Having thus noticed the movements of these insects during the night,
I found they were almost always abroad and engaged about the dome of
their habitation after sunset. This was directly the reverse of what I
had observed in the conduct of the wood-ants (_F. rufa_), who only go
out during the day, and close their doors in the evening. The contrast
was still more remarkable than I had previously supposed; for, upon
visiting the brown ants some days after, during a gentle rain, I saw
all their architectural talents in full play.

"As soon as the rain commenced, they left in great numbers their
subterranean residence, re-entered it almost immediately, and then
returned, bearing between their teeth pellets of earth, which they
deposited on the roof of their nest. I could not at first conceive what
this was meant for, but at length I saw little walls start up on all
sides with spaces left between them. In several places, columns, ranged
at regular distances, announced halls, lodges, and passages which the
ants proposed establishing; in a word, it was the rough beginning of a
new story.

"I watched with a considerable degree of interest the most trifling
movements of my masons, and found they did not work after the manner
of wasps and humble-bees, when occupied in constructing a covering
to their nest. The latter sit, as it were, astride on the border or
margin of the covering, and take it between their teeth to model and
attenuate it according to their wish. The wax of which it is composed,
and the paper which the wasp employs, moistened by some kind of glue,
are admirably adapted for this purpose, but the earth of which the ants
make use, from its often possessing little tenacity, must be worked up
after some other manner.

"Each ant, then, carried between its teeth the pellet of earth it had
formed by scraping with the end of its mandibles the bottom of its
abode, a circumstance which I have frequently witnessed in open day.
This little mass of earth, being composed of particles but just united,
could be readily kneaded and moulded as the ants wished; thus when
they had applied it to the spot where they had to rest, they divided
and pressed against it with their teeth, so as to fill up the little
inequalities of their wall. The antennae followed all their movements,
passing over each particle of earth as soon as it was placed in its
proper position. The whole was then rendered more compact by pressing
it lightly with the fore-feet. This work went on remarkably fast.
After having traced out the plan of their masonry, in laying here and
there foundations for the pillars and partitions they were about to
erect, they raised them gradually higher, by adding fresh materials.
It often happened that two little walls, which were to form a gallery,
were raised opposite, and at a slight distance from each other. When
they had attained the height of four or five lines, the ants busied
themselves in covering in the space left between them by a vaulted
ceiling.

"As if they judged all their partitions of sufficient elevation, they
then quitted their labours in the upper part of the building; they
affixed to the interior and upper part of each wall fragments of
moistened earth, in an almost horizontal direction, and in such a way
as to form a ledge, which, by extension, would be made to join that
coming from the opposite wall. These ledges were about half a line in
thickness; and the breadth of the galleries was, for the most part,
about a quarter of an inch. On one side several vertical partitions
were seen to form the scaffolding of a lodge, which communicated with
several corridors by apertures formed in the masonry; on another, a
regularly-formed hall was constructed, the vaulted ceiling of which
was sustained by numerous pillars; further off, again, might be
recognised the rudiments of one of those cross roads of which I have
before spoken, and in which several avenues terminate. These parts of
the ant-hill were the most spacious; the ants, however, did not appear
embarrassed in constructing the ceiling to cover them in, although they
were often more than two inches in breadth.

"In the upper part of the angles formed by the different walls, they
laid the first foundations of this ceiling, and from the top of each
pillar, as from so many centres, a layer of earth, horizontal and
slightly convex, was carried forward to meet the several portions
coming from different points of the large public thoroughfare.

"I sometimes, however, laboured under an apprehension that the building
could not possibly resist its own weight, and that such extensive
ceilings, sustained only by a few pillars, would fall into ruin from
the rain which continually dropped upon them; but I was quickly
convinced of their stability, from observing that the earth brought by
these insects adhered at all points, on the slightest contact; and that
the rain, so far from lessening the cohesion of its particles, appeared
even to increase it. Thus, instead of injuring the building, it even
contributed to render it still more secure.

"These particles of moistened earth, which are only held together by
juxtaposition, require a fall of rain to cement them more closely,
and thus varnish over, as it were, those places where the walls and
galleries remain uncovered. All inequalities in the masonry then
disappear. The upper part of these stories, formed of several pieces
brought together, presents but one single layer of compact earth. They
require for their complete consolidation nothing but the heat of the
sun. It sometimes, however, happens that a violent rain will destroy
the apartments, especially should they be but slightly arched; but
under these circumstances the ants reconstruct them with wonderful
patience.

"These different labours were carried on at the same time, and were
so closely followed up in the different quarters, that the ant-hill
received an additional story in the course of seven or eight hours. All
the vaulted ceilings being formed upon a regular plan, and at equal
distances from one wall to the other, constituted, when finished, but
one single roof. Scarcely had the ants finished one story than they
began to construct another; but they had not time to finish it--the
rain ceasing before the ceiling was fully completed. They still,
however, continued their work for a few hours, taking advantage of
the humidity of the earth; but a keen north wind soon sprung up, and
hastily dried the collected fragments, which, no longer possessing
the same adherence, readily fell into powder. The ants, finding their
efforts ineffectual, were at length discouraged, and abandoned their
employment; but what was my astonishment when I saw them destroy all
the apartments that were yet uncovered, scattering here and there over
the last story the materials of which they had been composed! These
facts incontestably prove that they employ neither gum, nor any kind of
cement, to bind together the several substances of their nest; but in
place of this avail themselves of the rain, to work or knead the earth,
leaving the sun and wind to dry and consolidate it."[CW]

Dr. Johnson of Bristol observed very similar proceedings in the case
of a colony of red ants (_Myrmica rubra?_), the roof of whose nest was
formed by a flat stone. During dry weather, a portion of the side walls
fell in; but the rubbish was quickly removed, though no repairs were
attempted till a shower of rain enabled them to work. As soon as this
occurred, they worked with extraordinary rapidity, and in a short time
the whole of the fallen parts were rebuilt, and rendered as smooth as
if polished with a trowel.

When a gardener wishes to water a plot of ground where he has sown
seeds that require nice management, he dips a strong brush into
water, and passes his hand backwards and forwards over the hairs for
the purpose of producing a fine artificial shower. Huber successfully
adopted the same method to excite his ants to recommence their labours,
which had been interrupted for want of moisture. But sometimes, when
they deem it unadvisable to wait for rain, they dig down (as we
remarked to be the practice of the mason-bees) till they arrive at
earth sufficiently moist for their purpose. They do not, however, like
these bees, merely dig for materials; for they use the excavations for
apartments, as well as what they construct with the materials thence
derived. They appear, in short, to be no less skilful in mining than in
building.

Such is the general outline of the operations of this singular species;
but we are still more interested with the history which M. P. Huber
has given of the labours of an individual ant. "One rainy day," he
says, "I observed a labourer of the dark ash-<DW52> species (_Formica
fusca_) digging the ground near the aperture which gave entrance to
the ant-hill. It placed in a heap the several fragments it had scraped
up, and formed them into small pellets, which it deposited here and
there upon the nest. It returned constantly to the same place, and
appeared to have a particular design, for it laboured with ardour and
perseverance. I remarked a slight furrow, excavated in the ground in a
straight line, representing the plan of a path or gallery. The labourer
(the whole of whose movements fell under my immediate observation) gave
it greater depth and breadth, and cleared out its borders; and I saw,
at length--in which I could not be deceived--that it had the intention
of establishing an avenue which was to lead from one of the stories
to the underground chambers. This path, which was about two or three
inches in length, and formed by a single ant, was opened above, and
bordered on each side by a buttress of earth. Its concavity, in the
form of a pipe (_gouttiere_), was of the most perfect regularity: for
the architect had not left an atom too much. The work of this ant was
so well followed and understood, that I could almost to a certainty
guess its next proceeding, and the very fragment it was about to
remove. At the side of the opening where this path terminated was a
second opening, to which it was necessary to arrive by some road. The
same ant began and finished this undertaking without assistance. It
furrowed out and opened another path, parallel to the first, leaving
between each a little wall of three or four lines in height."

Like the hive-bees, ants do not seem to work in concert, but each
individual separately. There is, consequently, an occasional want of
coincidence in the walls and arches; but this does not much embarrass
them, for a worker, on discovering an error of this kind, seems to know
how to rectify it, as appears from the following observations:--

"A wall," says M. Huber, "had been erected, with the view of sustaining
a vaulted ceiling, still incomplete, that had been projected towards
the wall of the opposite chamber. The workman who began constructing
it had given it too little elevation to meet the opposite partition,
upon which it was to rest. Had it been continued on the original plan,
it must infallibly have met the wall at about one-half of its height;
and this it was necessary to avoid. This state of things very forcibly
claimed my attention; when one of the ants arriving at the place, and
visiting the works, appeared to be struck by the difficulty which
presented itself; but this it as soon obviated, by taking down the
ceiling, and raising the wall upon which it reposed. It then, in my
presence, constructed a new ceiling with the fragments of the former
one.

"When the ants commence any undertaking, one would suppose that they
worked after some preconceived idea, which, indeed, would seem verified
by the execution. Thus, should any ant discover upon the nest two
stalks of plants which lie crossways, a disposition favourable to
the construction of a lodge, or some little beams that may be useful
in forming its angles and sides, it examines the several parts with
attention; then distributes, with much sagacity and address, parcels
of earth in the spaces, and along the stems, taking from every quarter
materials adapted to its object, sometimes not caring to destroy the
work that others had commenced; so much are its motions regulated
by the idea it has conceived, and upon which it acts, with little
attention to all else around it. It goes and returns, until the plan is
sufficiently understood by its companions.

"In another part of the same ant-hill," continues M. Huber, "several
fragments of straw seemed expressly placed to form the roof of a large
house: a workman took advantage of this disposition. These fragments
lying horizontally, at half-an-inch distance from the ground, formed,
in crossing each other, an oblong parallelogram. The industrious insect
commenced by placing earth in the several angles of this framework,
and all along the little beams of which it was composed. The same
workman afterwards placed several rows of the same materials against
each other, when the roof became very distinct. On perceiving the
possibility of profiting by another plant to support a vertical wall,
it began laying the foundations of it; other ants having by this time
arrived, finished in common what this had commenced."[CX]

[Illustration]

M. Huber made most of his observations upon the processes followed by
ants in glazed artificial hives or formicaries. The preceding figure
represents a view of one of his formicaries of mason-ants.

We have ourselves followed up his observations, both on natural
ant-hills and in artificial formicaries. On digging cautiously into a
natural ant-hill, established upon the edge of a garden-walk, we were
enabled to obtain a pretty complete view of the interior structure.
There were two stories, composed of large chambers, irregularly oval,
communicating with each other by arched galleries, the walls of all
which were as smooth and well-polished as if they had been passed over
by a plasterer's trowel. The floors of the chambers, we remarked, were
by no means either horizontal or level, but all more or less sloped,
and exhibiting in each chamber at least two slight depressions of an
irregular shape. We left the under story of this nest untouched, with
the notion that the ants might repair the upper galleries, of which
we had made a vertical section; but instead of doing so they migrated
during the day to a large crack formed by the dryness of the weather,
about a yard from their old nest. (J. R.)

[Illustration]

We put a number of yellow ants (_Formica flava_), with their eggs
and cocoons, into a small glass frame, more than half full of moist
sand taken from their native hill, and placed in a sloping position,
in order to see whether they would bring the nearly vertical, and
therefore insecure, portion to a level by masonry. We were delighted to
perceive that they immediately resolved upon performing the task which
had been assigned them, though they did not proceed very methodically
in their manner of building; for instead of beginning at the bottom
and building upwards, many of them went on to add to the top of the
outer surface, which increased rather than diminished the insecurity
of the whole. Withal, however, they seemed to know how far to go, for
no portion of the newly-built wall fell; and in two days they had not
only reared a pyramidal mound to prop the rest, but had constructed
several galleries and chambers for lodging the cocoons, which we had
scattered at random amongst the sand. The new portion of this building
is represented in the figure as supporting the upper and insecure parts
of the nest.

[Illustration]

We are sorry to record that our ingenious little masons were found
upon the third day strewed about the outside of the building dead or
dying, either from over-fatigue or perhaps from surfeit, as we had
supplied them with as much honey as they could devour. A small colony
of turf-ants have at this moment (July 28th, 1829) taken possession of
the premises of their own accord. (J. R.)




_CHAPTER XV._

STRUCTURES OF THE WOOD-ANT OR PISMIRE, AND OF CARPENTER-ANTS.


The largest of our British ants is that called the Hill-ant by Gould,
the Fallow-ant by the English translator of Huber, and popularly
the Pismire; but which we think may be more appropriately named the
Wood-ant (_Formica rufa_, Latr.), from its invariable habit of living
in or near woods and forests. This insect may be readily distinguished
from other ants by the dusky black colour of its head and hinder
parts, and the rusty brown of its middle. The structures reared by
this species are often of considerable magnitude, and bear no small
resemblance to a rook's nest thrown upon the ground bottom upwards.
They occur in abundance in the woods near London, and in many other
parts of the country: in Oak of Honour Wood alone, we are acquainted
with the localities of at least two dozen,--some in the interior, and
others on the hedge-banks on the outskirts of the wood. (J. R.)

The exterior of the nest is composed of almost every transportable
material which the colonists can find in their vicinity; but the
greater portion consists of the stems of withered grass and short
twigs of trees, piled up in apparent confusion, but with sufficient
regularity to render the whole smooth, conical, and sloping towards
the base, for the purpose, we may infer, of carrying off rain-water.
When within reach of a corn-field, they often also pick up grains
of wheat, barley, or oats, and carry them to the nest as building
materials, and not for food, as was believed by the ancients. There
are wonders enough observable in the economy of ants, without having
recourse to fancy--wonders which made Aristotle extol the sagacity of
bloodless animals, and Cicero ascribe to them not only sensation, but
mind, reason, and memory.[CY] AElian, however, describes, as if he had
actually witnessed it, the ants ascending a stalk of growing corn, and
throwing down "the ears which they bit off to their companions below."
Aldrovand assures us that he had seen their granaries; and others
pretend that they shrewdly bite off the ends of the grain to prevent it
from germinating.[CZ] These are fables which accurate observation has
satisfactorily contradicted.

[Illustration: Nest of Wood-Ant.]

But these errors, as it frequently happens, have contributed to a
more perfect knowledge of the insects than we might otherwise have
obtained; for it was the wish to prove or disprove the circumstance of
their storing up and feeding upon grain which led Gould to make his
observations on English ants; as the notion of insects being produced
_from_ putrid carcases had before led Redi to his ingenious experiments
on their generation. Yet, although it is more than eighty years since
Gould's book was published, we find the error still repeated in very
respectable publications.[DA]

The coping which we above described as forming the exterior of the
wood-ant's nest, is only a small portion of the structure, which
consists of a great number of interior chambers and galleries, with
funnel-shaped avenues leading to them. The coping, indeed, is one of
the most essential parts, and we cannot follow a more delightful guide
than the younger Huber in detailing its formation.

"The labourers," he says, "of which the colony is composed, not only
work continually on the outside of their nest, but, differing very
essentially from other species, who willingly remain in the interior,
sheltered from the sun, they prefer living in the open air, and do not
hesitate to carry on, even in our presence, the greater part of their
operations.

"To have an idea how the straw or stubble-roof is formed, let us take
a view of the ant-hill at its origin, when it is simply a cavity in
the earth. Some of its future inhabitants are seen wandering about
in search of materials fit for the exterior work, with which, though
rather irregularly, they cover up the entrance; whilst others are
employed in mixing the earth, thrown up in hollowing the interior,
with fragments of wood and leaves, which are every moment brought in
by their fellow-assistants; and this gives a certain consistence to
the edifice, which increases in size daily. Our little architects
leave here and there cavities, where they intend constructing the
galleries which are to lead to the exterior, and as they remove in
the morning the barriers placed at the entrance of their nest the
preceding evening, the passages are kept open during the whole time
of its construction. We soon observed the roof to become convex; but
we should be greatly deceived did we consider it solid. This roof is
destined to include many apartments or stories. Having observed the
motions of these little builders through a pane of glass, adjusted
against one of their habitations, I am thence enabled to speak with
some degree of certainty upon the manner in which they are constructed.
I ascertained that it is by excavating or mining the under portion of
their edifice that they form their spacious halls--low, indeed, and of
heavy construction, yet sufficiently convenient for the use to which
they are appropriated, that of receiving, at certain hours of the day,
the larvae and pupae.

"These halls have a free communication by galleries, made in the same
manner. If the materials of which the ant-hill is composed were only
interlaced, they would fall into a confused heap every time the ants
attempted to bring them into regular order. This, however, is obviated
by their tempering the earth with rain-water, which, afterwards
hardened in the sun, so completely and effectually binds together the
several substances, as to permit the removal of certain fragments
from the ant-hill without any injury to the rest; it, moreover,
strongly opposes the introduction of the rain. I never found, even
after long and violent rains, the interior of the nest wetted to more
than a quarter of an inch from the surface, provided it had not been
previously out of repair, or deserted by its inhabitants.

"The ants are extremely well sheltered in their chambers, the largest
of which is placed nearly in the centre of the building; it is much
loftier than the rest, and traversed only by the beams that support the
ceiling; it is in this spot that all the galleries terminate, and this
forms, for the most part, their usual residence.

"As to the underground portion, it can only be seen when the ant-hill
is placed against a declivity; all the interior may be then readily
brought in view, by simply raising up the straw roof. The subterranean
residence consists of a range of apartments, excavated in the earth,
taking an horizontal direction."[DB]

[It seems rather surprising that the wood-ants should be able, with
such materials as they employ, to make a dome-shaped structure, which
shall be furnished with cells and galleries, and yet shall endure rain
and wind, without being penetrated by the one or blown away by the
other. If the hill be closely examined, the little sticks of which it
is composed will be seen to have a definite, though not very regular
arrangement; and it is a noteworthy circumstance that the longest
are preserved for the galleries, being laid across each other in a
very ingenious manner, so as to prevent the material from falling and
filling up the galleries. This structure was shown very clearly in a
huge ant-hill in Bagshot Park. We introduced a sheet of plate glass
into the nest, so as to divide it perpendicularly into two halves, and
having given the insects six weeks to repair damages, we removed one
half of the hill, so that the whole interior of the other half could
be seen through the glass. The whole economy of the nest was thus made
clear, and the artificial arrangement of the materials showed itself
very plainly on the roofs of the cells and galleries.]

[Illustration]

M. P. Huber, in order to observe the operations of the wood-ant
with more attention, transferred colonies of them to his artificial
formicaries, plunging the feet of the stand into water to prevent their
escape till they were reconciled to their abode, and had made some
progress in repairing it.

[Under the glass shade on the top of the formicary may be seen the
mound which the wood-ants have raised, according to their custom, and
below, through the glass front, the reader may see the various passages
and cells which communicate with the hill above. As the ants require
that the lower part of their dwelling should be in darkness, a stout
wooden door can be shut over the glass to exclude the light.]

There is this remarkable difference in the nest of the wood-ants, that
they do not construct a long covert way as if for concealment, as
the yellow and the brown ants do. The wood-ants are not, like them,
afraid of being surprised by enemies, at least during the day, when
the whole colony is either foraging in the vicinity or employed on the
exterior. But the proceedings of the wood-ants at night are well worthy
of notice; and when M. Huber began to study their economy, he directed
his entire attention to their night proceedings. "I remarked," says
he, "that their habitations changed in appearance hourly, and that the
diameter of those spacious avenues, where so many ants could freely
pass each other during the day, was, as night approached, gradually
lessened. The aperture, at length, totally disappeared, the dome was
closed on all sides, and the ants retired to the bottom of their nest.

"In further noticing the apertures of these ant-hills, I fully
ascertained the nature of the labour of its inhabitants, of which I
could not before even guess the purport; for the surface of the nest
presented such a constant scene of agitation, and so many insects were
occupied in carrying materials in every direction, that the movement
offered no other image than that of confusion.

"I saw then clearly that they were engaged in stopping up passages; and
for this purpose they at first brought forward little pieces of wood,
which they deposited near the entrance of those avenues they wished to
close; they placed them in the stubble; they then went to seek other
twigs and fragments of wood, which they disposed above the first, but
in a different direction, and appeared to choose pieces of less size in
proportion as the work advanced. They, at length, brought in a number
of dried leaves, and other materials of an enlarged form, with which
they covered the roof: an exact miniature of the art of our builders,
when they form the covering of any building. Nature, indeed, seems
everywhere to have anticipated the inventions of which we boast, and
this is doubtless one of the most simple.

"Our little insects, now in safety in their nest, retire gradually
to the interior before the last passages are closed; one or two only
remain without, or concealed behind the doors on guard, while the
rest either take their repose, or engage in different occupations in
the most perfect security. I was impatient to know what took place in
the morning upon these ant-hills, and therefore visited them at an
early hour. I found them in the same state in which I had left them
the preceding evening. A few ants were wandering about on the surface
of the nest, some others issued from time to time from under the
margin of their little roofs formed at the entrance of the galleries;
others afterwards came forth, who began removing the wooden bars that
blockaded the entrance, in which they readily succeeded. This labour
occupied them several hours. The passages were at length free, and the
materials with which they had been closed scattered here and there over
the ant-hill. Every day, morning and evening, during the fine weather,
I was a witness to similar proceedings. On days of rain the doors of
all the ant-hills remained closed. When the sky was cloudy in the
morning, or rain was indicated, the ants, who seemed to be aware of it,
opened but in part their several avenues, and immediately closed them
when the rain commenced."[DC]

The galleries and chambers which are roofed in as thus described are
very similar to those of the mason-ants, being partly excavated in the
earth, and partly built with the clay thence procured. It is in these
they pass the night, and also the colder months of the winter, when
they become torpid, or nearly so, and of course require not the winter
granaries of corn with which the ancients fabulously furnished them.


Carpenter-Ants.

The ants that work in wood perform much more extensive operations
than any of the other carpenter insects which we have mentioned.
Their only tools, like those of bees and wasps, are their jaws or
mandibles; but though these may not appear so curiously constructed as
the ovipositor file of the tree-hopper (_Cicada_), or the rasp and saw
of the saw-flies (_Tenthredinidae_), they are no less efficient in the
performance of what is required. Among the carpenter-ants, the emmet or
jet-ant (_F. fuliginosa_) holds the first rank, and is easily known by
being rather less in size than the wood-ant, and by its fine shining
black colour. It is less common in Britain than some of the preceding,
though its colonies may occasionally be met with in the trunks of
decaying oak or willow trees in hedges.

"The labourers," says Huber, "of this species work always in the
interior of trees, and are desirous of being screened from observation:
thus every hope on our part is precluded of following them in their
several occupations. I tried every expedient I could devise to surmount
this difficulty; I endeavoured to accustom these ants to live and work
under my inspection, but all my efforts were unsuccessful; they even
abandoned the most considerable portion of their nest to seek some
new asylum, and spurned the honey and sugar which I offered them for
nourishment. I was now, by necessity, limited to the inspection only of
their edifices: but, by decomposing some of the fragments with care, I
hoped to acquire some knowledge of their organization.

"On one side I found horizontal galleries, hidden in great part by
their walls, which follow the circular direction of the layers of the
wood; and on another, parallel galleries, separated by extremely thin
partitions, having no communication except by a few oval apertures.
Such is the nature of these works, remarkable for their delicacy and
lightness.

"In other fragments I found avenues which opened laterally, including
portions of walls and transverse partitions, erected here and there
within the galleries, so as to form separate chambers. When the work
is further advanced, round holes are always observed, encased, as
it were, between two pillars cut out in the same wall. These holes
in course of time become square, and the pillars, originally arched
at both ends, are worked into regular columns by the chisel of our
sculptors. This, then, is the second specimen of their art. This
portion of the edifice will probably remain in this state.

"But in another quarter are fragments differently wrought, in which
these same partitions, pierced now in every part, and hewn skilfully,
are transformed into colonnades, which sustain the upper stories, and
leave a free communication throughout the whole extent. It can readily
be perceived how parallel galleries, hollowed out upon the same plan,
and the sides taken down, leaving only from space to space what is
necessary to sustain their ceilings, may form an entire story; but as
each has been pierced separately, the flooring cannot be very level:
this, however, the ants turn to their advantage, since these furrows
are better adapted to retain the larvae that may be placed there.

[Illustration: Portion of a Tree, with Chambers and Galleries chiseled
out by Jet-Ants.]

"The stories constructed in the great roots offer greater irregularity
than those in the very body of the tree, arising either from the
hardness and interlacing of the fibres, which renders the labour more
difficult, and obliges the labourers to depart from their accustomed
manner, or from their not observing in the extremities of their edifice
the same arrangement as in the centre: whatever it be, horizontal
stories and numerous partitions are still found. If the work be less
regular, it becomes more delicate; for the ants, profiting by the
hardness and solidity of the materials, give to their building an
extreme degree of lightness. I have seen fragments of from eight to
ten inches in length, and of equal height, formed of wood as thin
as paper, containing a number of apartments, and presenting a most
singular appearance. At the entrance of these apartments, worked out
with so much care, are very considerable openings; but in place of
chambers and extensive galleries, the layers of the wood are hewn in
arcades, allowing the ants a free passage in every direction. These
may be regarded as the gates or vestibules conducting to the several
lodges."[DD]

It is a singular circumstance in the structures of these ants, that all
the wood which they carve is tinged of a black colour, as if it were
smoked; and M. Huber was not a little solicitous to discover whence
this arose. It certainly does not add to the beauty of their streets,
which look as sombre as the most smoke-dyed walls in the older lanes
of the metropolis. M. Huber could not satisfy himself whether it was
caused by the exposure of the wood to the atmosphere, by some emanation
from the ants, or by the thin layers of wood being acted upon or
decomposed by the formic acid.[DE] But if any or all of these causes
operated in blackening the wood, we should be ready to anticipate a
similar effect in the case of other species of ants which inhabit
trees; yet the black tint is only found in the excavations of the
jet-ant.

We are acquainted with several colonies of the jet-ants (_Formica
fuliginosa_)--one of which, in the roots and trunk of an oak on the
road from Lewisham to Sydenham, near Brockley, in Kent, is so extremely
populous, that the numbers of its inhabitants appeared to us beyond any
reasonable estimate. None of the other colonies of this species which
we have seen appear to contain many hundreds. On cutting into the root
of the before-mentioned tree, we found the vertical excavations of much
larger dimensions, both in width and depth, than those represented by
Huber in the preceding cut (page 302). What surprised us the most was
to see the tree growing vigorously and fresh, though its roots were
chiseled in all directions by legions of workers, while every leaf, and
every inch of the bark, was also crowded by parties of foragers. On
one of the low branches we found a deserted nest of the white-throat
(_Sylvia cinerea_, Temminck), in the cavity of which they were piled
upon one another as close as the unhappy <DW64>s in the hold of a
slave-ship; but we could not discover what had attracted them hither.
Another dense group, collected on one of the branches, led us to the
discovery of a very singular oak gall, formed on the bark in the shape
of a pointed cone, and crowded together. It is probable that the juice
which they extracted from these galls was much to their taste. (J. R.)

[Illustration: F. fuliginosa.]

Beside the jet-ant, several other species exercise the art of
carpentry,--nay, what is more wonderful still, they have the ingenuity
to knead up, with spider's-web for a cement, the chips which they
chisel out into a material with which they construct entire chambers.
The species which exercise this singular art are the Ethiopian
(_Formica nigra_) and the yellow ant (_F. flava_).[DF]

We once observed the dusky ants (_F. fusca_) at Blackheath, in Kent,
busily employed in carrying out chips from the interior of a decaying
black poplar, at the root of which a colony was established; but,
though it thence appears that this species can chisel wood if they
choose, yet they usually burrow in the earth, and by preference, as we
have remarked, at the root of a tree, the leaves of which supply them
with food.

       *       *       *       *       *

Among the foreign ants we may mention a small yellow ant of South
America, described by Dampier, which seems, from his account, to
construct a nest of green leaves. "Their sting," he says, "is like
a spark of fire; and they are so thick among the boughs in some
places, that one shall be covered with them before he is aware. These
creatures have nests on great trees, placed on the body between the
limbs: some of their nests are as big as a hogshead. This is their
winter habitation; for in the wet season they all repair to these their
cities, where they preserve their eggs. In the dry season, when they
leave their nests, they swarm all over the woodlands, for they never
trouble the savannahs. Great paths, three or four inches broad, made by
them, may be seen in the woods. They go out light, but bring home heavy
loads on their backs, all of the same substance, and equal in size. I
never observed anything besides pieces of green leaves, so big that I
could scarcely see the insect for his burthen; yet they would march
stoutly, and so many were pressing forward that it was a very pretty
sight, for the path looked perfectly green with them."

Ants observed in New South Wales, by the gentlemen in the expedition
under Captain Cook, are still more interesting. "Some," we are told,
"are as green as a leaf, and live upon trees, where they build their
nests of various sizes, between that of a man's head and his fist.
These nests are of a very curious structure: they are formed by bending
down several of the leaves, each of which is as broad as a man's hand,
and gluing the points of them together, so as to form a purse. The
viscous matter used for this purpose is an animal juice which nature
has enabled them to elaborate. Their method of first bending down the
leaves we had no opportunity to observe; but we saw thousands uniting
all their strength to hold them in this position, while other busy
multitudes were employed within in applying this gluten that was to
prevent their returning back. To satisfy ourselves that the leaves
were bent and held down by the efforts of these diminutive artificers,
we disturbed them in their work; and as soon as they were driven from
their stations, the leaves on which they were employed sprang up with
a force much greater than we could have thought them able to conquer
by any combination of their strength. But, though we gratified our
curiosity at their expense, the injury did not go unrevenged; for
thousands immediately threw themselves upon us, and gave us intolerable
pain with their stings, especially those which took possession of our
necks and hair, from whence they were not easily driven. Their sting
was scarcely less painful than that of a bee; but, except it was
repeated, the pain did not last more than a minute.

"Another sort are quite black, and their operation and manner of life
are not less extraordinary. Their habitations are the inside of the
branches of a tree, which they contrive to excavate by working out
the pith almost to the extremity of the slenderest twig, the tree at
the same time flourishing as if it had no such inmate. When we first
found the tree we gathered some of the branches, and were scarcely
less astonished than we should have been to find that we had profaned
a consecrated grove, where every tree, upon being wounded, gave signs
of life; for we were instantly covered with legions of these animals,
swarming from every broken bough, and inflicting their stings with
incessant violence.

"A third kind we found nested in the root of a plant, which grows
on the bark of trees in the manner of mistletoe, and which they
had perforated for that use. This root is commonly as big as a
large turnip, and sometimes much bigger. When we cut it we found it
intersected by innumerable winding passages, all filled with these
animals, by which, however, the vegetation of the plant did not appear
to have suffered any injury. We never cut one of these roots that
was not inhabited, though some were not bigger than a hazel-nut. The
animals themselves are very small, not more than half as big as the
common red ant in England. They had stings, but scarcely force enough
to make them felt: they had, however, a power of tormenting us in an
equal, if not in a greater degree; for the moment we handled the root,
they swarmed from innumerable holes, and running about those parts of
the body that were uncovered, produced a titillation more intolerable
than pain, except it is increased to great violence."[DG]

The species called sugar-ants in the West Indies are particularly
destructive to the sugar-cane, as well as to lime, lemon, and
orange-trees, by excavating their nests at the roots, and so loosening
the earth that they are frequently uprooted and blown down by the
winds. If this does not happen, the roots are deprived of due
nourishment, and the plants become sickly and die.[DH]

[One or two examples of foreign ants are well worthy of notice. The
first of them is an insect whose habits bear strongly upon the familiar
passage in Proverbs, ch. vi. v. 6:--

    "Go to the ant, thou sluggard; consider her ways, and be wise:
    Which having no guide, overseer, or ruler,
    Provideth her meat in the summer, and gathereth her food in the harvest."

This passage is one that has been often mentioned as a proof that the
Bible is not to be implicitly trusted. Judging from all the species of
ants known to entomologists, some writers argue that the author of the
proverb in question was ignorant of the real history of the ant, and
was taking up a popular fallacy.

[Still, although the ants of the old world are chiefly carnivorous, or
feed on soft substances, and in consequence have not the least idea
of hoarding food for the winter, there is one species of Brazilian
ant which absolutely builds houses, prepares ground, sows seed, reaps
the grain, and stores it away for future consumption. It is the
Agricultural Ant, _Atta malefaciens_, first described by Dr. Lincecum,
who watched the insect for twelve years before publishing an account
that he knew would at first be received with incredulity. The following
abstract of his paper appeared in the Journal of the Linnaean Society.

"The species which I have named 'Agricultural' is a large brownish
ant. It dwells in what may be termed paved cities, and like a thrifty,
diligent, provident farmer, makes suitable and timely arrangements for
the changing seasons. It is, in short, endowed with skill, ingenuity,
and untiring patience, sufficient to enable it successfully to contend
with the varying exigencies which it may have to encounter in the life
conflict.

"When it has selected a situation for its habitation, if on ordinary
dry ground, it bores a hole, around which it raises the surface three
and sometimes six inches, forming a low circular mound, having a very
gentle inclination from the centre to the outer border, which on an
average is three or four feet from the entrance. But if the location is
chosen on low, flat, wet land, liable to inundation, though the ground
may be perfectly dry at the time the ant sets to work, it nevertheless
elevates the mound, in the form of a pretty sharp cone, to the height
of fifteen or twenty inches or more, and makes the entrance near the
summit. Around the mound, in either case, the ant clears the ground
of all obstructions, and levels and marks the surface to the distance
of three or four feet from the gate of the city, giving the space the
appearance of a handsome pavement, as it really is.

"Within this paved area not a blade of any green thing is allowed to
grow, except a single species of grain-bearing grass. Having planted
this crop in a circle around, and two or three feet from the centre
of the mound, the insect tends and cultivates it with constant care,
cutting away all other grasses and weeds that may spring up amongst it,
and all around outside the farm circle to the extent of one or two feet
more. The cultivated grass grows luxuriantly, and produces a heavy crop
of small, white, flinty seeds, which under the microscope very closely
resemble ordinary rice. When ripe, it is carefully harvested and
carried by the workers, chaff and all, into the granary cells, where it
is divested of the chaff and packed away. The chaff is taken out and
thrown beyond the limits of the paved area.

"During protracted wet weather it sometimes happens that the
provision-stores become damp, and are liable to sprout and spoil. In
this case, on the first fine day, the ants bring out the damp and
damaged grain, and expose it to the sun till it is dry, when they carry
it back and pack away all the sound seeds, leaving those that had
sprouted to waste.

"In a peach orchard not far from my house is a considerable elevation,
on which is an extensive bed of rock. In the sand-beds overlying
portions of this rock are five cities of the agricultural ants,
evidently very ancient. My observations on their manners and customs
have been limited to the last twelve years, during which time the
inclosure surrounding the orchard has prevented the approach of cattle
to the ant-farms. The cities which are outside the inclosure, as well
as those protected in it, are at the proper season invariably planted
with the ant-rice. The crop may accordingly always be seen springing up
within the circle about the 1st of November every year. Of late years,
however, since the number of farms and cattle has greatly increased,
and the latter are eating off the grass much closer than formerly, thus
preventing the ripening of the seeds, I notice that the agricultural
ant is placing its cities along the turn-rows in the fields, walks in
gardens, inside about the gates, &c., where they can cultivate their
farms without molestation from the cattle.

"There can be no doubt that the particular species of grain-bearing
grass mentioned above is intentionally planted. In farmer-like manner
the ground upon which it stands is carefully divested of all other
grasses and weeds during the time it is growing. When it is ripe, the
grain is taken care of, the dry stubble cut away and carried off, the
paved area being left unencumbered until the ensuing autumn, when the
same ant-rice reappears within the same circle, and receives the same
agricultural attention as was bestowed upon the previous crop--and so
on, year after year, as I _know_ to be the case, in all situations
where the ants' settlements are protected from granivorous animals."

This interesting account is simply the result of twelve years' patient
investigation on the part of Dr. Lincecum, who took special care not to
invent a theory and to twist facts in accordance with it, but watched
the entire proceedings of the insects for a series of years.

[Illustration: Crematogaster.]

The preceding illustration represents the rather remarkable nest of
an Australian ant, belonging to the genus Crematogaster. This word
signifies "hanging-belly," and the name has been applied to the ant in
consequence of the manner in which its abdomen is held up in the air,
so that it overhangs the back.

As may be seen, the nest is of considerable size, and might from its
external appearance be mistaken for that of a wasp. The interior of it,
however, is even more elaborate, being full of little covered passages
interlacing with each other in a most intricate manner, but all leading
to the internal galleries.

The two nests which are shown in the next illustration are, if
possible, still more remarkable.

[Illustration]

The upper one is found in Cayenne, and is made by an insect called the
fungus ant (_Polyrachis bispinosa_), because the nest looks as if it
were made of fungus. It is not, however, composed of that material,
but of the fibre of the cotton-tree (_Bombax ceiba_).

The fibre is in itself very short, barely exceeding an inch in length,
but it is cut very much shorter by the ant, who contrives to felt it
together in a most curious manner, so that it is hardly possible to
trace the course of any one fibre. The size of the nest is, on an
average, about eight or nine inches in diameter. The insect itself is
given in the preceding illustration, but very much enlarged. If the
reader will look at the centre of the body, he will see the projections
which have given it the name of _bispinosa_, or two-spined.

The lower figure represents the nest of another species of ant
belonging to the same genus, and called scientifically, _Polyrachis
textor_. The nest is most ingeniously made of little pieces of wood and
tendrils, put together so as to form a kind of open net-work, through
which the interior of the nest is plainly visible. This insect inhabits
Malacca.]




_CHAPTER XVI_.

STRUCTURES OF WHITE ANTS, OR TERMITES.


When we look back upon the details which we have given of the industry
and ingenuity of numerous tribes of insects, both solitary and social,
we are induced to think it almost impossible that they could be
surpassed. The structures of wasps and bees, and still more those of
the wood-ant (_Formica rufa_), when placed in comparison with the size
of the insects, equal our largest cities compared with the stature
of man. But when we look at the buildings erected by the white ants
of tropical climates, all that we have been surveying dwindles into
insignificance. Their industry appears greatly to surpass that of our
ants and bees, and they are certainly more skilful in architectural
contrivances. The elevation, also, of their edifices is more than
five hundred times the height of the builders. Were our houses built
according to the same proportions, they would be twelve or fifteen
times higher than the London Monument, and four or five times higher
than the pyramids of Egypt, with corresponding dimensions in the
basements of the edifices. These statements are, perhaps, necessary to
impress the extraordinary labours of ants upon the mind; for we are
all more or less sensible to the force of comparisons. The analogies
between the works of insects and of men are not perfect; for insects
are all provided with instruments peculiarly adapted to the end which
they instinctively seek, while man has to form a plan by progressive
thought, and upon the experience of others, and to complete it with
tools which he also invents.

The termites do not stand above a quarter of an inch high, while their
nests are frequently twelve feet, and Jobson mentions some which he had
seen as high as twenty feet; "of compass," he adds, "to contain a dozen
men, with the heat of the sun baked into that hardness, that we used
to hide ourselves in the ragged tops of them when we took up stands to
shoot at deer or wild beasts."[DI] Bishop Heber saw a number of these
high ant-hills in India, near the principal entrance of the Sooty or
Moorshedabad river. "Many of them," he says, "were five or six feet
high, and probably seven or eight feet in circumference at the base,
partially overgrown with grass and ivy, and looking at a distance like
the stumps of decayed trees. I think it is Ctesias, among the Greek
writers, who gives an account alluded to by Lucian in his 'Cock,' of
monstrous ants in India, as large as foxes. The falsehood probably
originated in the stupendous fabrics which they rear here, and which
certainly might be supposed to be the work of a much larger animal
than their real architect."[DJ] Herodotus has a similar fable of the
enormous size and brilliant appearance of the ants of India.

Nor is it only in constructing dwellings for themselves that the
termites of Africa and of other hot climates employ their masonic
skill. Though, like our ants and wasps, they are almost omnivorous, yet
wood, particularly when felled and dry, seems their favourite article
of food; but they have an utter aversion to feeding in the light, and
always eat their way with all expedition to the interior. It thence
would seem necessary for them either to leave the bark of a tree, or
the outer portion of the beam or door of a house, undevoured, or to eat
in open day. They do neither; but are at the trouble of constructing
galleries of clay, in which they can conceal themselves, and feed in
security. In all their foraging excursions, indeed, they build covert
ways, by which they can go out and return to their encampment.[DK]

Others of the species (for there are several), instead of building
galleries, exercise the art of miners, and make their approaches under
ground, penetrating beneath the foundation of houses or areas, and
rising again either through the floors, or by entering the bottom of
the posts that support the building, when they follow the course of
the fibres, and make their way to the top, boring holes and cavities
in different places as they proceed. Multitudes enter the roof, and
intersect it with pipes or galleries, formed of wet clay, which serve
for passages in all directions, and enable them more readily to fix
their habitations in it. They prefer the softer woods, such as pine
and fir, which they hollow out with such nicety, that they leave the
surface whole, after having eaten away the inside. A shelf or plank
attacked in this manner looks solid to the eye, when, if weighed, it
will not out-balance two sheets of pasteboard of the same dimensions.
It sometimes happens that they carry this operation so far on stakes
in the open air, as to render the bark too flexible for their purpose;
when they remedy the defect by plastering the whole stick with a sort
of mortar which they make with clay, so that, on being struck, the form
vanishes, and the artificial covering falls in fragments on the ground.
In the woods, when a large tree falls from age or accident, they enter
it on the side next the ground, and devour it at leisure, till little
more than the bark is left. But in this case they take no precaution of
strengthening the outward defence, but leave it in such a state as to
deceive an eye unaccustomed to see trees thus gutted of their insides:
and "you may as well," says Mr. Smeathman, "step upon a cloud." It is
an extraordinary fact, that when these creatures have formed pipes in
the roof of a house, instinct directs them to prevent its fall, which
would ensue from their having sapped the posts on which it rests; but
as they gnaw away the wood, they fill up the interstices with clay,
tempered to a surprising degree of hardness, so that, when the house
is pulled down, these posts are transformed from wood to stone. They
make the walls of their galleries of the same composition as their
nests, varying the materials according to their kind; one species using
the red clay, another black clay, and the third a woody substance,
cemented with gums, as a security from the attacks of their enemies,
particularly the common ant, which, being defended by a strong, horny
shell, is more than a match for them, and when it can get at them,
rapaciously seizes them, and drags them to its nest for food for its
young brood. If any accident breaks down part of their walls, they
repair the breach with all speed. Instinct guides them to perform their
office in the creation, by mostly confining their attacks to trees that
are beginning to decay, or such timber as has been severed from its
roots for use, and would decay in time. Vigorous, healthy trees do not
require to be destroyed, and accordingly, these consumers have no taste
for them.[DL]

M. Adanson describes the termites of Senegal as constructing covert
ways along the surface of wood which they intend to attack; but though
we have no reason to distrust so excellent a naturalist, in describing
what he saw, it is certain that they more commonly eat their way into
the interior of the wood, and afterwards form the galleries, when they
find that they have destroyed the wood till it will no longer afford
them protection.

But it is time that we should come to their principal building, which
may, with some propriety, be called a city; and, according to the
method we have followed in other instances, we shall trace their
labours from the commencement. We shall begin with the operations of
the species which may be appropriately termed the Warrior (_Termes
fatalis_, Linn.; _T. bellicosus_, Smeath.).

We must premise, that though they have been termed white _ants_, they
do not belong to the same order of insects with our ants; yet they
have a slight resemblance to ants in their form, but more in their
economy. Smeathman, to whom we owe our chief knowledge of the genus,
describes them as consisting of kings, queens, soldiers, and workers,
and is of opinion that the workers are larvae, the soldiers nymphae, and
the kings and queens the perfect insects. In this opinion he coincides
with Sparrmann[DM] and others; but Latreille is inclined to think,
from what he observed in a European species (_Termes lucifugus_) found
near Bordeaux, that the soldiers form a distinct race, like the neuter
workers among bees and ants, while the working termites are larvae,[DN]
which are furnished with strong mandibles for gnawing; when they become
nymphs, the rudiments of four wings appear, which are fully developed
in the perfect insects.

[Illustration: Termes bellicosus in the winged state.]

[It is now known that the differences of form among the termites are
accounted for as follows. The winged specimens are the fully developed
males and females, popularly called kings and queens. These crawl to
the aperture of their house and take flight, retiring to earth after
a short time. When a male and female meet each other, they cast off
their wings exactly as do the ants of our own country, and become the
founders of a new colony. Their soldiers are undeveloped males, and the
workers are undeveloped females.]

In the winged state, they migrate to form new colonies, but the greater
number of them perish in a few hours, or become the prey of birds, and
even of the natives, who fry them as delicacies. "I have discoursed
with several gentlemen," says Smeathman, "upon the taste of the white
ants, and on comparing notes, we have always agreed that they are most
delicious and delicate eating. One gentleman compared them to sugared
marrow, another to sugared cream and a paste of sweet almonds."[DO]

Mr. Smeathman's very interesting paper affords us the most authentic
materials for the further description of these wonderful insects; and
we therefore continue partly to extract from, and partly to abridge,
his account.

The few pairs that are so fortunate as to survive the various
casualties that assail them, are usually found by workers (larvae),
which, at this season, are running continually on the surface of the
ground, on the watch for them. As soon as they discover the objects
of their search, they begin to protect them from their surrounding
enemies, by inclosing them in a small chamber of clay, where they
become the parents of a new community, and are distinguished from the
other inhabitants of the nest by the title of king and queen. Instinct
directs the attention of these labouring insects to the preservation
of their race, in the protection of this pair and their offspring.
The chamber that forms the rudiment of a new nest is contrived for
their safety, but the entrances to it are too small to admit of their
ever leaving it; consequently, the charge of the eggs devolves upon
the labourers, who construct nurseries for their reception. These are
small, irregularly-shaped chambers, placed at first round the apartment
of the king and queen, and not exceeding the size of a hazel-nut; but
in nests of long standing they are of great comparative magnitude, and
distributed at a greater distance. The receptacles for hatching the
young are all composed of wooden materials, apparently joined together
with gum, and, by way of defence, cased with clay. The chamber that
contains the king and queen is nearly on a level with the surface of
the ground; and as the other apartments are formed about it, it is
generally situated at an equal distance from the sides of the nest,
and directly beneath its conical point. Those apartments which consist
of nurseries and magazines of provisions, form an intricate labyrinth,
being separated by small, empty chambers and galleries, which surround
them, or afford a communication from one to another. This labyrinth
extends on all sides to the outward shells, and reaches up within it
to two-thirds or more of its height, leaving an open area above, in
the middle, under the dome, which reminds the spectator of the nave of
an old cathedral. Around this are raised three or four large arches,
which are sometimes two or three feet high, next the front of the area,
but diminish as they recede further back, and are lost amidst the
innumerable chambers and nurseries behind them.

Every one of these buildings consists of two distinct parts, the
exterior and the interior. The exterior is one large shell, in the
manner of a dome, large and strong enough to inclose and shelter the
interior from the vicissitudes of the weather, and the inhabitants from
the attacks of natural or accidental enemies. It is always, therefore,
much stronger than the interior building, which is the habitable part,
divided, with a wonderful kind of regularity and contrivance, into an
amazing number of apartments for the residence of the king and queen,
and the nursing of the numerous progeny; or for magazines, which are
always found well filled with stores and provisions. The hills make
their first appearance above ground by a little turret or two, in the
shape of sugar-loaves, which are run a foot high or more. Soon after,
at some little distance, while the former are increasing in height and
size, they raise others, and so go on increasing their number, and
widening them at the base, till their works below are covered with
these turrets, of which they always raise the highest and largest
in the middle, and by filling up the intervals between each turret,
collect them into one dome. They are not very curious or exact in the
workmanship, except in making them very solid and strong; and when,
by their joining them, the dome is completed, for which purpose the
turrets answer as scaffolds, they take away the middle ones entirely,
except the tops, which, joined together, make the crown of the cupola,
and apply the clay to the building of the works within, or to erecting
fresh turrets for the purpose of raising the hillock still higher; so
that some part of the clay is probably used several times, like the
boards and posts of a mason's scaffold.

When these hills are little more than half their height, it is a common
practice of the wild bulls to stand as sentinels on them, while the
rest of the herd are ruminating below. They are sufficiently strong
for that purpose, and at their full height answer excellently well as
places of look-out; and Mr. Smeathman has been, with four more, on
the top of one of these hillocks, to watch for a vessel in sight. The
outward shell, or dome, is not only of use to protect and support the
interior buildings from external violence and the heavy rains, but
to collect and preserve a regular degree of the warmth and moisture
necessary for hatching the eggs and cherishing the young. The royal
chamber occupied by the king and queen appears to be, in the opinion
of this little people, of the most consequence, being always situated
as near the centre of the interior building as possible. It is always
nearly in the shape of half an egg, or an obtuse oval, within, and may
be supposed to represent a long oven. In the infant state of the colony
it is but about an inch in length; but in time will be increased to
six or eight inches, or more, in the clear, being always in proportion
to the size of the queen, who, increasing in bulk as in age, at length
requires a chamber of such dimensions.

[Illustration: Queen distended with Eggs.]

Its floor is perfectly horizontal, and in large hillocks, sometimes
more than an inch thick of solid clay. The roof, also, which is one
solid and well-turned oval arch, is generally of about the same
solidity; but in some places it is not a quarter of an inch thick on
the sides where it joins the floor, and where the doors or entrances
are made level with it, at nearly equal distances from each other.
These entrances will not admit any animal larger than the soldiers or
labourers; so that the king and the queen (who is, at full size, a
thousand times the weight of a king) can never possibly go out, but
remain close prisoners.

[There is a good series of the queen cells of the Termite in the
British Museum, and the reader is strongly recommended to go and
examine them. Some of them are as large as cocoa-nuts. Around the
cell are a number of small holes, looking as if they had been bored
with a bradawl. Now, if the cell be carefully opened, a most curious
arrangement will be seen. Each of the little holes serves as an opening
into a passage which communicates with the interior of the cell. The
apartment, if we may so call it, which contains the queen, is only
just large enough to hold her, and there is no door or opening for her
egress. This, however, is not required, as her enormous size prevents
her from moving. Through these passages runs incessantly a stream of
worker termites, some of them carrying eggs which the queen has just
laid, and others returning to the royal chamber for a fresh supply.]

The royal chamber, if in a large hillock, is surrounded by a countless
number of others, of different sizes, shapes, and dimensions; but all
of them arched in one way or another--sometimes elliptical or oval.
These either open into each other, or communicate by passages as wide
as, and are evidently made for, the soldiers and attendants, of whom
great numbers are necessary, and always in waiting. These apartments
are joined by the magazines and nurseries. The former are chambers of
clay, and are always well filled with provisions, which, to the naked
eye, seem to consist of the raspings of wood, and plants which the
termites destroy, but are found by the microscope to be principally
the gums or inspissated juices of plants. These are thrown together in
little masses, some of which are finer than others, and resemble the
sugar about preserved fruits; others are like tears of gum, one quite
transparent, another like amber, a third brown, and a fourth quite
opaque, as we see often in parcels of ordinary gums. These magazines
are intermixed with the nurseries, which are buildings totally
different from the rest of the apartments; for these are composed
entirely of wooden materials, seemingly joined together with gums. Mr.
Smeathman calls them the nurseries because they are invariably occupied
by the eggs and young ones, which appear at first in the shape of
labourers, but white as snow. These buildings are exceedingly compact,
and divided into many very small irregular-shaped chambers, not one
of which is to be found of half an inch in width. They are placed all
round, and as near as possible to the royal apartments.

When the nest is in the infant state, the nurseries are close to the
royal chambers; but as, in process of time, the queen enlarges, it is
necessary to enlarge the chamber for her accommodation; and as she
then lays a greater number of eggs, and requires a greater number of
attendants, so it is necessary to enlarge and increase the number of
the adjacent apartments; for which purpose the small nurseries which
are first built are taken to pieces, rebuilt a little further of a size
larger, and the number of them increased at the same time. Thus they
continually enlarge their apartments, pull down, repair, or rebuild,
according to their wants, with a degree of sagacity, regularity, and
foresight, not even imitated by any other kind of animals or insects.

All these chambers, and the passages leading to and from them, being
arched, they help to support each other; and while the interior large
arches prevent them from falling into the centre, and keep the area
open, the exterior building supports them on the outside. There are,
comparatively speaking, few openings into the great area, and they,
for the most part, seem intended only to admit into the nurseries
that genial warmth which the dome collects. The interior building, or
assemblage of nurseries, chambers, &c., has a flattish top or roof,
without any perforation, which would keep the apartments below dry, in
case through accident the dome should receive any injury, and let in
water; and it is never exactly flat and uniform, because the insects
are always adding to it by building more chambers and nurseries; so
that the division or columns between the future arched apartment
resemble the pinnacles on the fronts of some old buildings, and demand
particular notice, as affording one proof that for the most part the
insects project their arches, and do not make them by excavation. The
area has also a flattish floor, which lies over the royal chamber,
but sometimes a good height above it, having nurseries and magazines
between. It is likewise waterproof, and contrived to let the water
off if it should get in, and run over by some short way into the
subterraneous passages, which run under the lowest apartments in the
hill in various directions, and are of an astonishing size, being
wider than the bore of a great cannon. One that Mr. Smeathman measured
was perfectly cylindrical, and thirteen inches in diameter. These
subterraneous passages, or galleries, are lined very thick with the
same kind of clay of which the hill is composed, and ascend the inside
of the outward shell in a spiral manner; and winding round the whole
building up to the top, intersect each other at different heights,
opening either immediately in the dome in various places, and into the
interior building, the new turrets, &c., or communicating with them by
other galleries of different diameters, either circular or oval.

From every part of these large galleries are various small covert
ways, or galleries leading to different parts of the building. Under
ground there are a great many that lead downward by sloping descents,
three and four feet perpendicular among the gravel, whence the workers
cull the finer parts, which, being kneaded up in their mouths to the
consistence of mortar, become that solid clay or stone of which their
hills and all their buildings, except their nurseries, are composed.
Other galleries again ascend, and lead out horizontally on every side,
and are carried under ground near to the surface a vast distance: for
if all the nests are destroyed within a hundred yards of a house, the
inhabitants of those which are left unmolested farther off will still
carry on their subterraneous galleries, and, invading it by sap and
mine, do great mischief to the goods and merchandise contained in it.

It seems there is a degree of necessity for the galleries under the
hills being thus large, since they are the great thoroughfares for
all the labourers and soldiers going forth or returning, whether
fetching clay, wood, water, or provisions; and they are certainly well
calculated for the purposes to which they are applied by the spiral
<DW72> which is given them; for if they were perpendicular the labourers
would not be able to carry on their building with so much facility, as
they ascend a perpendicular with great difficulty, and the soldiers can
scarcely do it at all. It is on this account that sometimes a road like
a ledge is made on the perpendicular side of any part of the building
within their hill, which is flat on the upper surface and half an inch
wide, and ascends gradually like a staircase, or like those winding
roads which are cut on the sides of hills and mountains, that would
otherwise be inaccessible; by which and similar contrivances they
travel with great facility to every interior part.

[Illustration: _a_, A covered way and nest, on the branch of a tree, of
the _Termites arborum_. _b_, Section of the Hill-nest of the _Termites
bellicosi_, to show the interior. _c_, Hill-nest of the _Termites
bellicosi_, entire.]

This, too, is probably the cause of their building a kind of bridge
of one great arch, which answers the purpose of a flight of stairs
from the floor of the area to some opening on the side of one of the
columns that support the great arches. This contrivance must shorten
the distance exceedingly to those labourers who have the eggs to carry
from the royal chamber to some of the upper nurseries, which in some
hills would be four or five feet in the straightest line, and much more
if carried through all the winding passages leading through the inner
chambers and apartments. Mr. Smeathman found one of these bridges, half
an inch broad, a quarter of an inch thick, and ten inches long, making
the side of an elliptic arch of proportionable size; so that it is
wonderful it did not fall over or break by its own weight before they
got it joined to the side of the column above.

It was strengthened by a small arch at the bottom, and had a hollow or
groove all the length of the upper surface, either made purposely for
the inhabitants to travel over with more safety, or else, which is not
improbable, worn by frequent treading.


Turret-building White Ants.

Apparently more than one species smaller than the preceding, such
as the _Termes mordax_ and _T. atrox_ of Smeathman, construct nests
of a very different form, the figures of which resemble a pillar,
with a large mushroom for a capital. These turrets are composed of
well-tempered black earth, and stand nearly three feet high. The
conical mushroom-shaped roof is composed of the same material, and
the brims hang over the column, being three or four inches wider than
its perpendicular sides. Most of them, says Smeathman, resemble in
shape the body of a round windmill, but some of the roofs have little
elevation in the middle. When one of these turrets is completed, the
insects do not afterwards enlarge or alter it; but if it be found too
small for them, they lay the foundation of another at a few inches'
distance. They sometimes, but not often, begin the second before the
first is finished, and a third before they have completed the second.
Five or six of these singular turrets in a group may be seen in the
thick woods at the foot of a tree. They are so very strongly built,
that in case of violence, they will sooner tear up the gravel and
solid heart of their foundation than break in the middle. When any of
them happen to be thus thrown down, the insects do not abandon them;
but, using their overturned column as a basis, they run up another
perpendicularly from it to the usual height, fastening the under part
at the same time to the ground, to render it the more secure.

The interior of a turret is pretty equally divided into innumerable
cells, irregular in shape, but usually more or less angular, generally
quadrangular or pentagonal, though the angles are not well defined.
Each shell has at least two entrances; but there are no galleries,
arches, nor wooden nurseries, as in the nests of the warrior (_T.
bellicosus_). The two species which build turret nests are very
different in size, and the dimensions of the nests differ in proportion.

[Illustration: Turret Nests of White Ants. One nest is represented cut
through, with the upper part lying on the ground.]


The White Ants of Trees.

Latreille's species of white ant (_Termes lucifugus_, Rossi), formerly
mentioned as found in the south of Europe, appear to have more the
habits of the jet-ant, described page 301, than their congeners of the
tropics. They live in the interior of the trunks of trees, the wood
of which they eat, and form their habitations of the galleries which
they thus excavate. M. Latreille says they appear to be furnished with
an acid for the purpose of softening the wood, the odour of which
is exceedingly pungent. They prefer the part of the wood nearest to
the bark, which they are careful not to injure, as it affords them
protection. All the walls of their galleries are moistened with small
globules of a gelatinous substance, similar to gum Arabic. They are
chiefly to be found in the trunks of oak and pine trees, and are very
numerous.[DP]

Another of the species (_Termes arborum_), described by Smeathman,
builds a nest on the exterior of trees, altogether different from any
of the preceding. These are of a spherical or oval shape, occupying
the arm or branch of a tree sometimes from seventy to eighty feet
from the ground, and as large, in a few instances, as a sugar-cask.
The composition used for a building material is apparently similar
to that used by the warriors for constructing their nurseries, being
the gnawings of wood in very small particles, kneaded into a paste
with some species of cement or glue, procured, as Smeathman supposes,
partly from gummiferous trees, and partly from themselves; but it is
more probable, we think, that it is wholly secreted, like the wax of
bees, by the insects themselves. With this cement, whatever may be its
composition, they construct their cells, in which there is nothing
very wonderful except their great numbers. They are very firmly built,
and so strongly attached to the trees, that they will resist the most
violent tornado. It is impossible, indeed, to detach them, except by
cutting them in pieces, or sawing off the branch, which is frequently
done to procure the insects for young turkeys. (See engraving, p. 324,
for a figure of this nest.)

This species very often, instead of selecting the bough of a tree,
builds in the roof or wall of a house, and unless observed in time,
and expelled, occasions considerable damage. It is easier, in fact,
to shut one's door against a fox or a thief, than to exclude such
insidious enemies, whose aversion to light renders it difficult to
trace them even when they are numerous.

[There are also termites in Europe, and the city of La Rochelle has
suffered terribly from them. They eat the trees in the gardens, and
not a stake can be driven into the ground, or even a plank left for
twenty-four hours, without being attacked. They also enter the houses
and utterly ruin them by eating every bit of timber that is used in
them. In one instance, where a room had been repaired, the stalactitic
galleries of the termites showed themselves the very day after the
workmen had left the room.

They invaded the prefecture, and did exceeding damage, one of their
feats of voracity being so extraordinary as to deserve mention. The
archives of the department were left in boxes, and privately inspected.
One day, when a paper was needed, the whole of the documents fell to
pieces, and were metamorphosed as if by magic into a heap of clay. The
termites had got into the boxes by boring through the wainscot of the
room, and had then penetrated among the papers. They consumed every
particle of them except the uppermost sheet and the edges, supplying
their place with clay. The consequence was, that although the heap of
documents seemed to be correct, there was nothing but a mass of clay
galleries and a single sheet of paper at the top.

So voracious are they, that even a piece of paper wrapped round a
bottle was eaten, the termites building a gallery of clay in order to
reach it under cover.]

If we reflect on the prodigious numbers of those insects, and their
power and rapidity of destroying, we cannot but admire the wisdom
of Providence in creating so indefatigable and useful an agent
in countries where the decay of vegetable substances is rapid in
proportion to the heat of the climate. We have already remarked that
they always prefer decaying or dead timber; and it is indeed a very
general law among insects which feed on wood to prefer what is
unsound; the same principle holds with respect to fungi, lichens, and
other parasitical plants.

All the species of Termites are not social; but the solitary ones do
not, like their congeners, distinguish themselves in architecture. In
other respects, their habits are more similar; for they destroy almost
every substance, animal and vegetable. The most common of the solitary
species must be familiar to all our readers by the name of wood-louse
(_Termes pulsatorium_, Linn.; _Atropos lignarius_, Leach)--one of
the insects which produces the ticking superstitiously termed the
_death-watch_. It is not so large as the common wood-louse, but whiter
and more slender, having a red mouth and yellow eyes. It lives in old
books, the paper on walls, collections of insects and dried plants,
and is extremely agile in its movements, darting, by jerks, into
dark corners for the purpose of concealment. It does not like to run
straight forward without resting every half-second, as if to listen
or look about for its pursuer, and at such resting times it is easily
taken. The ticking noise is made by the insect beating against the
wood with its head, and it is supposed by some to be peculiar to the
female, and to be connected with the laying of her eggs. M. Latreille,
however, thinks that the wood-louse is only the grub of the _Psocus
abdominalis_, in which case it could not lay eggs; but this opinion is
somewhat questionable. Another death-watch is a small beetle (_Anobium
tesselatum_).




_CHAPTER XVII._

STRUCTURES OF SILK SPUN BY CATERPILLARS, INCLUDING THE SILK-WORM.

        "Millions of spinning-worms,
    That in their green shops weave the smooth-hair'd silk."

    Milton's _Comus_.


All the caterpillars of butterflies, moths, and, in general, of insects
with four wings, are capable of spinning silk; of various degrees of
fineness and strength, and differing in colour, but usually white,
yellow, brown, black, or grey. This is not only of advantage in
constructing nests for themselves, and particularly for their pupae,
as we have so frequently exemplified in the preceding pages, but it
enables them, the instant they are excluded from the egg, to protect
themselves from innumerable accidents, as well as from enemies. If a
caterpillar, for instance, be exposed to a gust of wind, and blown off
from its native tree, it lets itself gently down, and breaks its fall,
by immediately spinning a cable of silk, along which, also, it can
reascend to its former station when the danger is over. In the same way
it frequently disappoints a bird that has marked it out for prey, by
dropping hurriedly down from a branch, suspended to its never-failing
delicate cord. The leaf-rollers, formerly described, have the advantage
of other caterpillars in such cases, by being able to move as quickly
backwards as forwards; so that when a bird puts in its bill at one
end of the roll, the insect makes a ready exit at the other, and
drops along its thread as low as it judges convenient. We have seen
caterpillars drop in this way from one to six feet or more; and by
means of their cable, which they are careful not to break, they climb
back with great expedition to their former place.

The structure of their legs is well adapted for climbing up their
singular rope--the six fore-legs being furnished with a curved claw;
while the pro-legs (as they have been termed) are no less fitted for
holding them firm to the branch when they have regained it, being
constructed on the principle of forming a vacuum, like the leather
sucker with which boys lift and drag stones. The foot of the common
fly has a similar sucker, by which it is enabled to walk on glass, and
otherwise support itself against gravity. The different forms of the
leg and pro-leg of a spinning caterpillar are represented in the figure.

[Illustration: Leg and Pro-leg of a Caterpillar, greatly magnified.]

In order to understand the nature of the apparatus by which a
caterpillar spins its silk, it is to be recollected that its whole
interior structure differs from that of warm-blooded animals. It has,
properly speaking, no heart, though a long tubular _dorsal vessel_,
which runs along the back, and pulsates from twenty to one hundred
times per minute, has been called so by Malpighi and others, but
neither Lyonnet nor Cuvier could detect any vessel issuing from it, and
consequently the fluid which is analogous to blood has no circulation.
It differs also from the higher orders of animals in having no brain,
the nerves running along the body being only united by little knobs,
called ganglions. Another circumstance is, that it has no lungs,
and does not breathe by the mouth, but by air-holes, or spiracles,
eighteen in number, situated along the sides, in the middle of the
rings, as may be seen in the following figure from Lyonnet.

[Illustration: Caterpillar of the Goat Moth (_Cossus ligniperda_).]

These spiracles communicate on each side with tubes, that have been
called the wind-pipes (_tracheae_). The spinning apparatus is placed
near the mouth, and is connected with the silk-bags, which are long,
slender, floating vessels, containing a liquid gum. The bags are closed
at their lower extremity, become wider towards the middle, and more
slender towards the head, where they unite to form the spinning-tube,
or spinneret. The bags being in most cases longer than the body of the
caterpillar, necessarily lie in a convoluted state, like the intestines
of quadrupeds. The capacity, or rather the length, of the silk-bags
is in proportion to the quantity of silk required for spinning; the
_Cossus ligniperda_, for example, from living in the wood of trees
spins little, having a bag only one-fourth the length of that of the
silk-worm, though the caterpillar is at least twice the dimensions of
the latter. The following figure, taken from the admirable treatise
of Lyonnet on the anatomy of the _Cossus_, will render these several
organs more easily understood than any description.

The spinneret itself was supposed by Reaumur to have two outlets for
the silk; but Lyonnet, upon minute dissection, found that the two tubes
united into one before their termination; and he also assured himself
that it was composed of alternate slips of horny and membranaceous
substance,--the one for pressing the thread into a small diameter,
and the other for enlarging it at the insect's pleasure. It is cut at
the end somewhat like a writing-pen, though with less of a <DW72>, and
is admirably fitted for being applied to objects to which it may be
required to attach silk. The following are magnified figures of the
spinneret of the _Cossus_, from Lyonnet.

[Illustration: Interior Structure of the Cossus.--A, silk bags; B, silk
tube, through which the viscid matter, of which the silk threads are
formed, is forced by a peristaltic motion; C, stomach; D D, intestines,
with the coil of bile vessels.]

[Illustration: Side-view of the Silk-tube.]

[Illustration: Section of the Silk-tube, magnified 22,000 times.]

[Illustration: Labium, or lower lip of Cossus.--_a_, Silk-tube.]

"You may sometimes have seen," says the Abbe de la Pluche, "in the
work-rooms of goldsmiths or gold wire-drawers, certain iron plates,
pierced with holes of different calibres, through which they draw gold
and silver wire, in order to render it finer. The silk-worm has under
her mouth such a kind of instrument, perforated with a pair of holes
[united into one on the outside[DQ],] through which she draws two drops
of the gum that fills her two bags. These instruments are like a pair
of distaffs for spinning the gum into a silken thread. She fixes the
first drop of gum that issues where she pleases, and then draws back
her head, or lets herself fall, while the gum, continuing to flow, is
drawn out and lengthened into a double stream. Upon being exposed to
the air, it immediately loses its fluidity, becomes dry, and acquires
consistence and strength. She is never deceived in adjusting the
dimensions of the [united] apertures, or in calculating the proper
thickness of the thread, but invariably makes the strength of it
proportionable to the weight of her body.

"It would be a very curious thing to know how the gum which composes
the silk is separated and drawn off from the other juices that nourish
the animal. It must be accomplished like the secretions formed by
glands in the human body. I am therefore persuaded that the gum-bags of
the silk-worm are furnished with a set of minute glands, which being
impregnated with gum, afford a free passage to all the juices of the
mulberry-leaf corresponding with this glutinous matter, while they
exclude every fluid of a different quality."[DR] When confined in an
open glass vessel, the goat-moth caterpillar will effect its escape by
constructing a curious silken ladder, as represented by Roesel.

Caterpillars, as they increase in size, cast their skins as lobsters
do their shells, and emerge into renewed activity under an enlarged
covering. Previous to this change, when the skin begins to gird and
pinch them, they may be observed to become languid, and indifferent to
their food, and at length they cease to eat, and await the sloughing of
their skin. It is now that the faculty of spinning silk seems to be of
great advantage to them; for, being rendered inactive and helpless by
the tightening of the old skin around their expanding body, they might
be swept away by the first puff of wind, and made prey of by ground
beetles or other carnivorous prowlers. To guard against such accidents,
as soon as they feel that they can swallow no more food, from being
half choked by the old skin, they take care to secure themselves from
danger by moorings of silk spun upon the leaf or the branch where they
may be reposing. The caterpillar of the white satin-moth (_Leucoma
salicis_, Stephens) in this way draws together with silk one or two
leaves, similar to the leaf-rollers (_Tortricidae_), though it always
feeds openly without any covering. The caterpillar of the puss-moth
again, which, in its third skin, is large and heavy, spins a thick web
on the upper surface of a leaf, to which it adheres till the change is
effected.

The most important operation, however, of silk-spinning is performed
before the caterpillar is transformed into a chrysalis, and is
most remarkable in the caterpillars of moths and other four-winged
flies, with the exception of those of butterflies; for though these
exhibit, perhaps, greater ingenuity, they seldom spin more than a
few threads to secure the chrysalis from falling, whereas the others
spin for it a complete envelope or shroud. We have already seen, in
the preceding pages, several striking instances of this operation,
when, probably for the purpose of husbanding a scanty supply of silk,
extraneous substances are worked into the texture. In the case of other
caterpillars, silk is the only material employed.

Of this the cocoon of the silk-worm is the most prominent example, in
consequence of its importance in our manufactures and commerce, and on
that account will demand from us somewhat minute details, though it
would require volumes to incorporate all the information which has been
published on the subject.


Silk-Worm.

The silk-worm, like most other caterpillars, changes its skin four
times during its growth. The intervals at which the four moultings
follow each other depend much on climate or temperature, as well as
on the quality and quantity of food. It is thence found, that if they
are exposed to a high temperature, say from 81 deg. to 100 deg. Fahrenheit,
the moultings will be hastened; and only five days will be consumed in
moulting the third or fourth time, whilst those worms that have not
been hastened take seven or eight days.[DS]

The period of the moultings is also influenced by the temperature in
which the eggs have been kept during the winter. When the heat of the
apartment has been regulated, the first moulting takes place on the
fourth or fifth day after hatching, the second begins on the eighth
day, the third takes up the thirteenth and fourteenth days, and the
last occurs on the twenty-second and twenty-third days. The fifth age,
in such cases, lasts ten days, at the end of which, or thirty-two days
after hatching, the caterpillars attain their full growth, and ought to
be three inches in length; but if they have not been properly fed, they
will not be so long.

With the age of the caterpillar, its appetite increases, and is at its
maximum after the fourth moulting, when it also attains its greatest
size. The silk gum is then elaborated in the reservoirs, while the
caterpillar ceases to eat, and soon diminishes again in size and
weight. This usually requires a period of nine or ten days, commencing
from the fourth moulting, after which it begins to spin its shroud of
silk. In this operation it proceeds with the greatest caution, looking
carefully for a spot in which it may be most secure from interruption.

"We usually," says the Abbe de la Pluche, "give it some little stalks
of broom, heath, or a piece of paper rolled up, into which it retires,
and begins to move its head to different places, in order to fasten its
thread on every side. All this work, though it looks to a bystander
like confusion, is not without design. The caterpillar neither arranges
its threads nor disposes one over another, but contents itself with
distending a sort of cotton or floss to keep off the rain; for Nature
having ordained silk-worms to work under trees, they never change their
method even when they are reared in our houses.

"When my curiosity led me to know how they spun and placed their
beautiful silk, I took one of them, and frequently removed the floss
with which it first attempted to make itself a covering; and as by
this means I weakened it exceedingly, when it at last became tired
of beginning anew, it fastened its threads on the first thing it
encountered, and began to spin very regularly in my presence, bending
its head up and down, and crossing to every side. It soon confined
its movements to a very contracted space, and, by degrees, entirely
surrounded itself with silk; and the remainder of its operations became
invisible, though these may be understood from examining the work
after it is finished. In order to complete the structure, it must draw
out of the gum-bag a more delicate silk, and then with a stronger gum
bind all the inner threads over one another.

"Here, then, are three coverings entirely different, which afford a
succession of shelter. The outer loose silk, or floss, is for keeping
off the rain; the fine silk in the middle prevents the wind from
causing injury; and the glued silk, which composes the tapestry of
the chamber where the insect lodges, repels both air and water, and
prevents the intrusion of cold.

"After building her cocoon, she divests herself of her fourth skin, and
is transformed into a chrysalis, and subsequently into a moth (_Bombyx
mori_), when, without saw or centre-bit, she makes her way through the
shell, the silk, and the floss; for the Being who teaches her how to
build herself a place of rest, where the delicate limbs of the moth may
be formed without interruption, instructs her likewise how to open a
passage for escape.

"The cocoon is like a pigeon's egg, and more pointed at one end
than the other; and it is remarkable that the caterpillar does not
interweave its silk towards the pointed end, nor apply its glue there
as it does in every other part,[DT] by bending itself all around with
great pliantness and agility: what is more, she never fails, when her
labour is finished, to fix her head opposite to the pointed extremity.
The reason of her taking this position is, that she has purposely
left this part less strongly cemented, and less exactly closed. She
is instinctively conscious that this is to be the passage for the
perfect insect which she carries in her bowels, and has therefore the
additional precaution never to place this pointed extremity against any
substance that might obstruct the moth at the period of its egress.

"When the caterpillar has exhausted herself to furnish the labour and
materials of the three coverings, she loses the form of a worm; her
spoils drop all around the chrysalis; first throwing off the skin,
with the head and jaws attached to it, and the new skin hardening
into a sort of leathery consistence. Its nourishment is already in its
stomach, and consists of a yellowish mucus, but gradually the rudiments
of the moth unfold themselves,--the wings, the antennae, and the legs
becoming solid. In about a fortnight or three weeks, a slight swelling
in the chrysalis may be remarked, which at length produces a rupture in
the membrane that covers it, and by repeated efforts the moth bursts
through the leathery envelope into the chamber of the cocoon.

"The moth then extends her antennae, together with her head and feet,
towards the point of the cone, which not being thickly closed up in
that part gradually yields to her efforts; she enlarges the opening,
and at last comes forth, leaving at the bottom of the cone the ruins of
its former state--namely, the head and entire skin of the caterpillar,
which bear some resemblance to a heap of foul linen."[DU]

Reaumur was of opinion that the moth makes use of its eyes as a file,
in order to effect its passage through the silk; while Malpighi, Peck,
and others, believe that it is assisted by an acid which it discharges
in order to dissolve the gum that holds the fibres of the silk together
(see p. 338). Mr. Swayne denies that the threads are broken at all,
either by filing or solution; for he succeeded in unwinding a whole
cocoon from which the moth had escaped. The soiling of the cocoon by a
fluid, however, we may remark, is no proof of the acid; for all moths
and butterflies discharge a fluid when they assume wings, whether they
be inclosed in a cocoon or not; but it gives no little plausibility to
the opinion, that "the end of the cocoon is observed to be wetted for
an hour, and sometimes several hours, before the moth makes its way
out."[DV] Other insects employ different contrivances for escape, as we
have already seen, and shall still further exemplify.

It is the middle portion of the cocoon, after removing the floss or
loose silk on the exterior, which is used in our manufactures; and the
first preparation is to throw the cocoons into warm water, and to stir
them about with twigs, to dissolve any slight gummy adhesions which may
have occurred when the caterpillar was spinning. The threads of several
cones, according to the strength of the silk wanted, are then taken and
wound off upon a reel. The refuse, consisting of what we may call the
tops and bottoms of the cones, are not wound, but carded, like wool or
cotton, in order to form coarser fabrics. We learn from the fact of the
cocoons being generally unwound without breaking the thread, that the
insect spins the whole without interruption. It is popularly supposed,
however, that if it be disturbed during the operation by any sort of
noise, it will take alarm, and break its thread; but Latreille says
this is a vulgar error.[DW]

The length of the unbroken thread in a cocoon varies from six hundred
to a thousand feet; and as it is all spun double by the insect, it
will amount to nearly two thousand feet of silk, the whole of which
does not weigh above three grains and a half; five pounds of silk from
ten thousand cocoons is considerably above the usual average. When
we consider, therefore, the enormous quantity of silk which is used
at present, the number of worms employed in producing it will almost
exceed our comprehension. The manufacture of the silk, indeed, gives
employment, and furnishes subsistence, to several millions of human
beings; and we may venture to say, that there is scarcely an individual
in the civilized world who has not some article made of silk in his
possession.

In ancient times, the manufacture of silk was confined to the East
Indies and China, where the insects that produce it are indigenous. It
was thence brought to Europe in small quantities, and in early times
sold at so extravagant a price, that it was deemed too expensive even
for royalty. The Emperor Aurelian assigned the expense as a reason for
refusing his empress a robe of silk; and our own James I., before his
accession to the crown of England, had to borrow of the Earl of Mar a
pair of silk stockings to appear in before the English ambassador,
a circumstance which probably led him to promote the cultivation of
silk in England.[DX] The Roman authors were altogether ignorant of
its origin,--some supposing it to be grown on trees as hair grows
on animals,--others that it was produced by a shell-fish similar to
the mussel, which is known to throw out threads for the purpose of
attaching itself to rocks,--others that it was the entrails of a sort
of spider, which was fed for four years with paste, and then with the
leaves of the green willow, till it burst with fat,--and others that it
was the produce of a worm which built nests of clay and collected wax.
The insect was at length spread into Persia; and eggs were afterwards,
at the instance of the Emperor Justinian, concealed in hollow canes by
two monks, and conveyed to the Isle of Cos. This emperor, in the sixth
century, caused them to be introduced into Constantinople, and made an
object of public utility. They were thence successively cultivated in
Greece, in Arabia, in Spain, in Italy, in France, and in all places
where any hope could be indulged of their succeeding. In America the
culture of the silk-worm was introduced into Virginia in the time of
James I., who himself composed a book of instructions on the subject,
and caused mulberry-trees and silk-worms' eggs to be sent to the
colony. In Georgia, also, lands were granted on condition of planting
one hundred white mulberry-trees on every ten acres of cleared land.[DY]

The growth of the silk-worm has also been tried, but with no great
success, in this country. Evelyn computed that one mulberry-tree would
feed as many silk-worms annually as would produce seven pounds of
silk. "According to that estimate," says Barham,[DZ] "the two thousand
trees already planted in Chelsea Park (which take up one-third of
it) will make 14,000 lbs. weight of silk; to be commonly worth but
twenty shillings a pound, those trees must make 14,000_l._ per annum."
During the last century, some French refugees in the south of Ireland
made considerable plantations of the mulberry, and had begun the
cultivation of silk with every appearance of success; but since their
removal the trees have been cut down.[EA] In the vicinity of London,
also, a considerable plantation of mulberry-trees was purchased by the
British, Irish, and Colonial Silk Company in 1825; but we have not
learned whether this Company have any active measures now in operation.


The manufacture of silk was introduced into this country in 1718,
at Derby, by Mr. John Lombe, who travelled into Italy to obtain the
requisite information; but so jealous were the Italians of this, that
according to some statements which have obtained belief, he fell a
victim to their revenge, having been poisoned at the early age of
twenty-nine.[EB]

There are not only several varieties of the common silk-worm (_Bombyx
mori_), but other species of caterpillars, which spin silk capable of
being manufactured, though not of so good qualities as the common silk.
None of our European insects, however, seem to be well fitted for the
purpose, though it has been proposed by Fabricius and others to try
the crimson under-wing (_Catocala sponsa_, Schrank), &c. M. Latreille
quotes from the 'Recreations of Natural History,' by Wilhelm, the
statement that the cocoons of the emperor-moth (_Saturnia pavonia_)
had been successfully tried in Germany, by M. Wentzel Hegeer de
Berchtoldsdorf, under an imperial patent.

[Illustration: Cocoons of the Emperor-moth, cut open to show their
structure.]


Emperor-Moth.

The emperor-moth, indeed, is no less worthy of our attention with
respect to the ingenuity of its architecture than the beauty of
its colours, and has consequently attracted the attention of every
Entomologist. The caterpillar feeds on fruit-trees and on the willow,
and spins a cocoon, in the form of a Florence flask, of strong silk,
so thickly woven that it appears almost like damask or leather. It
differs from most other cocoons in not being closed at the upper or
smaller end, which terminates in a narrow circular aperture, formed
by the convergence of little bundles of silk, gummed together, and
almost as elastic as whalebone. In consequence of all these terminating
in needle-shaped points, the entrance of depredators is guarded
against, upon the principle which prevents the escape of a mouse from
a wire trap. The insect, however, not contented with this protection,
constructs another in form of a canopy or dome, within the external
aperture, so as effectually to shield the chrysalis from danger.
We have formerly remarked (page 210) that the caterpillar of the
_AEgeria asiliformis_ of Stephens in a similar way did not appear to be
contented with a covering of thin wood, without an additional bonnet of
brown wax. The cocoon of the emperor-moth, though thus in some measure
impenetrable from without, is readily opened from within; and when the
moth issues from its pupa case, it easily makes its way out without
either the acid or eye-files ascribed to the silk-worm. The elastic
silk gives way upon being pushed from within, and when the insect is
fairly out, it shuts again of its own accord, like a door with spring
hinges,--a circumstance which at first puzzled Roesel not a little when
he saw a fine large moth in his box, and the cocoon apparently in the
same state as when he had put it there. Another naturalist conjectures
that the converging threads are intended to compress the body of the
moth as it emerges, in order to force the fluids into the nervures
of the wings; for when he took the chrysalis previously out of the
cocoon, the wings of the moth never expanded properly.[EC] Had he been
much conversant with breeding insects, he would rather, we think,
have imputed this to some injury which the chrysalis had received.
We have witnessed the shrivelling of the wings which he alludes to,
in many instances, and not unfrequently in butterflies which spin no
cocoon. The shrivelling, indeed, frequently arises from the want of
a sufficient supply of food to the caterpillar in its last stage,
occasioning a deficiency in the fluids.

The elasticity of the cocoon is not peculiar to the emperor-moth. A
much smaller insect, the green cream-border-moth (_Tortrix chlorana_)
before mentioned (page 190), for its ingenuity in bundling up the
expanding leaves of the willow, also spins an elastic shroud for its
chrysalis, of the singular shape of a boat with the keel uppermost.
Like the caterpillar of _Pyralis strigulalis_ (page 217), whose
building, though of different materials, is exactly of the same form,
its first spins two approximating walls of whitish silk, of the form
required, and when these are completed, it draws them forcibly together
with elastic threads, so placed as to retain them closely shut. The
passage of the moth out of this cocoon might have struck Roesel as
still more marvellous than that of his emperor, in which there was at
least a small opening; while in the boat cocoon there is none. We have
now before us two of these, which we watched the caterpillars through
the process of building, in the summer of 1828, and from one only a
moth issued--the other, as often happens, having died in the chrysalis.
But what is most remarkable, it is impossible by the naked eye to tell
which of these two has been opened by the moth, so neatly has the
joining been finished. (J. R.)

Some species of moths spin a very slight silken tissue for their
cocoons, being apparently intended more to retain them from falling
than to afford protection from other accidents. The gipsy-moth
(_Hypogymna dispar_), rare in most parts of Britain, is one of these.
It selects for its retreat a crack in the bark of the tree upon which
it feeds, and over this spins only a few straggling threads. We found
last summer (1829), in the hole of an elm-tree in the Park at Brussels,
a group of half a dozen of these, that did not seem to have spun any
covering at all, but trusted to a curtain of moss (_Hypna_) which
margined the entrance. (J. R.) In a species nearly allied to this,
the yellow-tussock (_Dasychira pudibunda_, Stephens), the cocoon, one
of which we have now before us, is of a pretty close texture, and
interwoven with the long hairs of the caterpillar itself (see figure
_b_, page 17), which it plucks out piecemeal during the process of
building,--as is also done by the vapourer (_Orgyia antiqua_, Hubner),
and many others.

[Illustration: Cocoon of Arctia villica.]

[Illustration: Net-work cocoon.]

These are additional instances of the remarks we formerly made, that
caterpillars which spin a slight web are transformed into perfect
insects in a much shorter period than those which spin more substantial
ones. Thus the cream-spot tiger (_Arctia villica_, Stephens) lies in
chrysalis only three weeks, and therefore does not require a strong
web. It is figured above, along with another, which is still slighter,
though more ingeniously woven, being regularly meshed like net-work.

A very prettily-netted cocoon is constructed by the grub of a very
small grey weevil (_Hypera rumicis_), which is not uncommon in July,
on the seed spikes of docks (_Rumices_). This cocoon is globular, and
not larger than a garden pea, though it appears to be very large in
proportion to the pupa of the insect, reminding us not a little of the
carved ivory balls from China. The meshes of the net-work are also
large, but the materials are strong and of a waxy consistence. Upon
remarking that no netting was ever spun over the part of the plant
to which the cocoon was attached, we endeavoured to make them spin
cocoons perfectly globular by detaching them when nearly finished; but
though we tried four or five in this way, we could not make them add a
single mesh after removal, all of them making their escape through the
opening, and refusing to re-enter in order to complete their structure.
(J. R.)

The silk, if it may be so termed, spun by many species of larvae is
of a still stronger texture than the waxy silk of the little weevil
just mentioned. We recently met with a remarkable instance of this at
Lee, in the cocoons of one of the larger ichneumons (_Ophion Vinulae_?
Stephens), inclosed in that of a puss-moth (_Cerura Vinula_)--itself
remarkable for being composed of sand as well as wood, the fibres of
which had been scooped out of the underground cross-bar of an old
paling, to which it was attached. But the most singular portion of
this was the junction of the outer wall with the edges of the hollow
thus scooped out, which was formed of fibres of wood placed across
the fibres of the bar nearly at right angles, and strongly cemented
together, as if to form a secure foundation for the building.

In this nest were formed, surreptitiously introduced into the original
building, five empty cells of a black colour, about an inch long, and a
sixth of an inch in diameter; nearly cylindrical in form, but somewhat
flattened; vertical and parallel to one another, though slightly curved
on the inner side. The cells are composed of strong and somewhat
coarse fibres, more like the carbonized rootlets of a tree than silk,
and resembling in texture a piece of coarse milled cloth or felt, such
as is used for the bases of plated hats. It is worthy of remark, that
all these cells opened towards one end, as if the caterpillars which
constructed them had been aware that the wall of the puss-moth, in
which the flies would have to make a breach, was very hard, and would
require their united efforts to effect an escape. The importance of
such a precaution will appear more strikingly, when we compare it with
the instance formerly mentioned (page 215), in which only one ichneumon
had been able to force its way out. (J. R.)

[Illustration: Nest of Puss-moth, inclosing five cocoons of an
Ichneumon. Natural size.]

It appears indispensable to some grubs to be confined within a certain
space in order to construct their cocoons. We saw this well exemplified
in the instance of a grub of one of the mason-bees (_Osmia bicornis_),
which we took from its nest, and put into a box with the pollen paste
which the mother bee had provided for its subsistence. (See pages 45,
46.) When it had completed its growth, it began to spin, but in a
very awkward manner-attaching threads, as if at random, to the bits
of pollen which remained undevoured, and afterwards tumbling about to
another part of the box, as if dissatisfied with what it had done. It
sometimes persevered to spin in one place till it had formed a little
vaulted wall; but it abandoned at the least three or four of these in
order to begin others, till at length, as if compelled by the extreme
urgency of the stimulus of its approaching change, it completed a
shell of shining brown silk, woven into a close texture. Had the grub
remained within the narrow clay cell built for it by the mother bee,
it would, in all probability, not have thus exhausted itself in vain
efforts at building, which were likely to prevent it from ever arriving
at the perfect state--a circumstance which often happens in the
artificial breeding of insects. This bee, however, made its appearance
the following spring. (J. R.)

Besides silk, the cocoons of many insects are composed of other animal
secretions, intended to strengthen or otherwise perfect their texture.
We have already seen that some caterpillars pluck off their own hair
to interweave amongst their silk; there are others which produce
a peculiar substance for the same purpose. The lackey caterpillar
(_Clisiocampa neustria_, Curtis) in this manner lines its cocoon with
pellets of a downy substance, resembling little tufts of the flowers
of sulphur. The small egger, again (_Eriogaster lanestris_, Germar),
can scarcely be said to employ silk at all,--the cocoon being of a
uniform texture, looking, at first sight, like dingy Paris plaster, or
the shell of a pheasant's egg; but upon being broken, and inspected
narrowly, a few threads of silk may be seen interspersed through the
whole. In size it is not larger than the egg of the gold-crested
wren. It has been considered by Brahm a puzzling circumstance, that
this cocoon is usually perforated with one or two little holes, as if
made by a pin from without; and Kirby and Spence tell us that their
use has not been ascertained.[ED] May they not be left as air-holes
for the included chrysalis, as the close texture of the cocoon might,
without this provision, prove fatal to the animal? Yet, on comparing
one of these with a similar cocoon of the large egger-moth (_Lasiocampa
quercus_), we find no air-holes in the latter, as we might have been
led to expect from the closeness of its texture. We found a cocoon of
a saw-fly (_Trichiosoma_), about the same size as that of the egger,
attached to a hawthorn-twig, in a hedge at New Cross, Deptford, but of
a leathery texture, and, externally, exactly the colour of the bark of
the tree. During the summer of 1830 we found a considerable number of
the same cocoons. These were all without air-holes. The egger, we may
remark, unlike the dock-weevil or the bee-grub just mentioned, can work
her cocoon without any point of attachment. We had a colony of these
caterpillars in the summer of 1825, brought from Epping Forest, and saw
several of them work their cocoons, and we could not but admire the
dexterity with which they avoided filling up the little pin-holes. The
supply of their building material was evidently measured out to them
in the exact quantity required; for when we broke down a portion of
their wall, by way of experiment, they did not make it above half the
thickness of the previous portion, though they plainly preferred having
a thin wall to leaving the breach unclosed. (J. R.)

Several species of caterpillars, that spin only silk, are social, like
some of those we formerly mentioned, which unite to form a common
tent of leaves (see pages 351, 352, &c.). The most common instance
of this is in the caterpillars which feed on the nettle--the small
tortoise-shell (_Vanessa urticae_), and the peacock's eye (_V. I._).
Colonies of these may be seen, after midsummer, on almost every clump
of nettles, inhabiting a thin web of an irregular oval shape, from
which they issue out to feed on the leaves, always returning when
their appetite is satisfied, to assist their companions in extending
their premises. Other examples, still more conspicuous from being seen
on fruit-trees and in hedges, occur in the caterpillars of the small
ermine-moth (_Yponomeuta padella_), and of the lackey (_Clisiocampa
neustria_), which in some years are but too abundant, though in others
they are seldom met with. In the summer of 1826, every hedge and
fruit-tree around London swarmed with colonies of the ermine, though
it has not since been plentiful; and in the same way, during the
summer of 1829, the lackeys were to be seen everywhere. We mention
this irregularity of appearance that our readers may not disappoint
themselves by looking for what is not always to be found. It is
probable that in 1830 the lackeys will be few, for, notwithstanding the
myriads of caterpillars last summer, we saw only a single moth of this
species, and out of a number of chrysalides which a young friend had in
his nurse-boxes, not one moth was bred.

The small ermine does not, besides, feed so indiscriminately as many
others, but when the bird-cherry (_Prunus padus_), its peculiar
food, is not to be had, it will put up with blackthorn, plum-tree,
hawthorn, and almost any sort of orchard fruit-tree. With respect to
such caterpillars as feed on different plants, Reaumur and De Geer
make the singular remark, that in most cases they would only eat the
sort of plant upon which they were originally hatched.[EE] We verified
this, in the case of the caterpillar in question, upon two different
nests which we took, in 1806, from the bird-cherry at Crawfordland,
in Ayrshire. Upon bringing these to Kilmarnock, we could not readily
supply them with the leaves of this tree; and having then only a slight
acquaintance with the habits of insects, and imagining they would eat
any sort of leaf, we tried them with almost everything green in the
vicinity of the town; but they refused to touch any which we offered
them. After they had fasted several days, we at length procured some
fresh branches of the bird-cherry, with which they gorged themselves so
that most of them died. Last summer (1829) we again tried a colony of
these caterpillars, found on a seedling plum-tree at Lee, in Kent, with
blackthorn, hawthorn, and many other leaves, and even with those of the
bird-cherry; but they would touch nothing except the seedling plum,
refusing the grafted varieties. (J. R.)

A circumstance not a little remarkable in so very nice a feeder is,
that in some cases the mother moth will deposit her eggs upon trees
not of indigenous growth, and not even of the same genus with her
usual favourites. Thus, in 1825, the cherry-apple, or Siberian crab
(_Pyrus prunifolia_, Willdenow), so commonly grown in the suburbs of
London, swarmed with them. On a single tree at Islington we counted
above twenty nests, each of which would contain from fifty to a hundred
caterpillars; and though these do not grow thicker than a crow-quill,
so many of them scarcely left a leaf undevoured, and, of course, the
fruit, which showed abundantly in spring, never came to maturity. The
summer following they were still more abundant on the hawthorn hedges,
particularly near the Thames, by Battersea and Richmond. Since then we
have only seen them sparingly; and last summer we could only find the
single nest upon which we tried the preceding experiment. (J. R.)

[Illustration: Encampment of the caterpillar of the small ermine
(_Yponomeuta padella_) on the Siberian crab.]

The caterpillars of other moths, which are in some years very
common--such as the brown-tail (_Porthesia auriflua_), and the
golden-tail (_P. chrysorrhoea_), are also social; and, as the eggs
are hatched late in the summer, the brood passes the winter in a
very closely-woven nest of warm silk. This is usually represented as
composed of leaves which have had their pulpy parts eaten as food by
the colonists; but from minute observation of at least twenty of these
nests in the winter of 1828-9, we are quite satisfied that leaves
are only an accidental, and not a necessary, part of the structure.
When a leaf happens to be in the line of the walls of the nest, it
is included; but there is no apparent design in pressing it into the
service, nor is a branch selected because it is leafy. On the contrary,
by far the greater number of these nests do not contain a single
leaf, but are composed entirely of grey silk. In external form, no
two of these nests are alike; as it depends entirely upon the form of
the branch. When, therefore, there is only one twig, it is somewhat
egg-shaped; but when there are several twigs, it commonly joins each,
assuming an angular shape, as may be seen in the left-hand figure.

[Illustration: Winter nests of _Porthesia chrysorrhoea_, one being
cut open to show the chambers. The dots represent the egesta of the
caterpillars.]

This irregularity arises from the circumstance of each individual
acting on its own account, without the direction or superintendence of
the others. The interior of the structure is, for the same reason, more
regular, being divided into compartments, each of which forms a chamber
for one or more individuals. Previous to the cold weather, these
chambers have but slight partitions; but before the frosts set in the
whole is made thick and warm.

[Illustration: Winter nest of the Social Caterpillars of the Brown-tail
Moth (_Porthesia auriflua_), figured from specimen.]

None of the preceding details, however, appear so striking as what
is recorded of the brown-tail moth (_Porthesia auriflua_) by Mr. W.
Curtis,[EF] whose multitudinous colonies spread great alarm over the
country in the summer of 1782. This alarm was much increased by the
exaggeration and ignorant details which found their way into the
newspapers. The actual numbers of these caterpillars must have been
immense, since Curtis says, "in many of the parishes near London
subscriptions have been opened, and the poor people employed to cut off
the webs at one shilling per bushel, which have been burnt under the
inspection of the church-wardens, overseers, or beadle of the parish:
at the first onset of this business fourscore bushels, as I was most
credibly informed, were collected in one day in the parish of Clapham."

It is not, therefore, very much to be wondered at, that the ignorant,
who are so prone to become the victims of groundless fears, should have
taken serious alarm on having so unusual a phenomenon forced upon their
attention. Some alarmists accordingly asserted that the caterpillars
"were the usual presage of the plague;" and others that they not only
presaged it, but would actually cause it, for "their numbers were great
enough to render the air pestilential;" while, to add to the mischief,
"they would destroy every kind of vegetation, and starve the cattle
in the fields." "Almost every one," adds Curtis, "ignorant of their
history, was under the greatest apprehensions concerning them; so that
even prayers were offered up in some churches to deliver the country
from the apprehended approaching calamity."

It seems to have been either the same caterpillar, or one very
nearly allied to it, probably that of the golden-tail (_Porthesia
chrysorrhoea_), which in 1731-2 produced a similar alarm in France.
Reaumur, on going from Paris to Tours, in September, 1730, found every
oak, great and small, literally swarming with them, and their leaves
parched and brown as if some burning wind had passed over them; for
when newly hatched, like the young buff-tips, they only eat one of the
membranes of the leaf, and of course the other withers away. These
infant legions, under the shelter of their warm nests, survived the
winter in such numbers, that they threatened the destruction not only
of the fruit-trees, but of the forests,--every tree, as Reaumur says,
being overrun with them. The Parliament of Paris thought that ravages
so widely extended loudly called for their interference, and they
accordingly issued an edict, to compel the people to uncaterpillar
(_decheniller_) the trees; which Reaumur ridiculed as impracticable, at
least in the forests. About the middle of May, however, a succession
of cold rains produced so much mortality among the caterpillars, that
the people were happily released from the edict; for it soon became
difficult to find a single individual of the species.[EG] In the same
way the cold rains, during the summer of 1829, seem to have nearly
annihilated the lackeys, which in the early part of the summer swarmed
on every hedge around London. The ignorance displayed in France, at the
time in question, was not inferior to that recorded by Curtis; for the
French journalists gravely asserted that part of the caterpillars were
produced by spiders; and that these spiders, and not the caterpillars,
constructed the webs of the slime of snails, which they were said to
have been seen collecting for the purpose! "Verily," exclaims Reaumur,
"there is more ignorance in our age than one might believe."

It is justly remarked by Curtis, that the caterpillar of the brown-tail
moth is not so limited a feeder as some, nor so indiscriminate as
others; but that it always confines itself to trees or shrubs, and is
never found on herbaceous plants, whose low growth would seldom supply
a suitable foundation for its web. Hence the absurdity of supposing
it would attack the herbage of the field, and produce a famine among
cattle. Curtis says, it is found on the "hawthorn most plentifully, oak
the same, elm very plentifully, most fruit-trees the same, blackthorn
plentifully, rose-trees the same, bramble the same, on the willow and
poplar scarce. None have been noticed on the elder, walnut, ash, fir,
or herbaceous plants. With respect to fruit-trees the injuries they
sustain are most serious, as, in destroying the blossoms as yet in the
bud, they also destroy the fruit in embryo; the owners of orchards,
therefore, have great reason to be alarmed."

The sudden appearance of great numbers of these caterpillars in
particular years, and their scarcity in others, is in some degree
explained by a fact stated by Mr. Salisbury. "A gentleman of Chelsea,"
he says, "has informed me that he once took a nest of moths and bred
them; that some of the eggs came the first year, some the second, and
others of the same nest did not hatch till the third season."[EH] We
reared, during 1829, several nests both of the brown-tails and of
the golden-tails, and a number of the females deposited their eggs
in our nurse-cages; but, contrary to the experiment just quoted, all
of these were hatched during the same autumn. (J. R.) The difference
of temperature and moisture in particular seasons may produce this
diversity.

A no less remarkable winter nest, of a small species of social
caterpillar, is described by M. Bonnet, which we omitted to introduce
when treating of the Glanville fritillary. The nest in question is
literally pendulous, being hung from the branch of a fruit tree by
a strong silken thread. It consists of one or two leaves neatly
folded, and held together with silk, in which the caterpillars live
harmoniously together.

[Illustration: Pendulous leaf-nests, from Bonnet.]

In a recently-published volume of 'Travels in Mexico,' we find a very
remarkable account of some pendulous nests of caterpillars, which
appear to be almost as curious as the nests of the pasteboard-making
wasps, described at p. 177. The author of these Travels does not
define the species of caterpillar whose constructions attracted his
observation. He says, "After having ascended for about an hour, we came
to the region of oaks and other majestically tall trees, the names of
which I could not learn. Suspended from their stately branches were
innumerable nests, enclosed, apparently, in white paper bags, in the
manner of bunches of grapes in England, to preserve them from birds and
flies. I had the curiosity to examine one of them, which I found to
contain numberless caterpillars. The texture is so strong that it is
not easily torn; and the interior contained a quantity of green leaves,
to support the numerous progeny within."[EI]

[We will now give a brief account of several foreign insects that are
remarkable for the pendulous nests which they make.

The first of these is built by a hymenopterous insect belonging to the
genus Larrada. It is fastened to the under side of a leaf, and is made
of vegetable fibres, cut up very short, and masticated by the insect,
much like the materials used by the Fungus Ant, described on page 311.
The insect which forms this nest is black in colour and has very thick
legs. The wings are clouded. It is but a small insect, being only
three-eighths of an inch in length. Both nest and insect are in the
collection of Mr. F. Smith, of the British Museum.

[Illustration: Nest of Larrada.]

In the next illustration are seen two nests built by hymenopterous
insects belonging to the hymenopterous genus Polybia. The left-hand
figure represents a nest made by Polybia sedula, a Brazilian insect. It
is fixed to a large leaf, and, as may be seen, has the entrance at the
end of a long neck. The exterior of the nest is a very thin sheet of
pale-brown substance, almost identical with the paper with which our
British wasps make their nests. It is, however, very much stronger and
very much thinner, and is very close in texture, so that it effectually
excludes rain.

[Illustration: Nests of Polybia.]

The right-hand figure shows a nest also brought from Brazil. It has
no neck, the opening being a mere hole beneath. The name Polybia
is derived from two Greek words signifying that many insects live
together, and has been given to the genus on account of the social
habits of its members.

Our next illustration contains some very remarkable nests.

The large central nest is the cocoon of a moth belonging to the genus
Oiketicus, or Housebuilder. There are many species of Housebuilder
moths, and all are remarkable for the fact that the larva never
exhibits itself, but builds a dwelling in which it conceals itself,
just as does the well-known caddis-worm. Indeed the nests of several
Oiketici look exactly as if the dwelling of a caddis-worm had been
greatly enlarged and hung up in a tree.

[Illustration: Nests of Oiketicus, &c.]

The nest of this species, however, differs from that of the common
Oiketicus by being covered with a coating of greyish silk. If we cut
open the silk, we find a great number of little sticks and leaf-stems
crossed on each other, and showing their ends through the silken cover.
Within these defences there is a layer of leaves cut into small pieces,
and lastly comes the cell inhabited by the caterpillar. It is lined
with a silken web similar in character to that on the outside, but
finer, stronger, and whiter The caterpillar is therefore defended by
four distinct barriers. First comes the strong silken web which lines
the cell, and next is the layer of leaf fragments. Outside them comes
the _chevaux de frise_ of crossed sticks, and lastly we have the grey
silken web. This outer wrapper has no connection with the interior of
the cell, and is only lightly attached to the ends of the cross sticks.

Within this curious dwelling the caterpillar conceals the whole of
its body, clinging to the branch or leaf by its feet, and if alarmed
drawing itself up so that the mouth of the cocoon is pressed tightly
against the branch, and effectually conceals even the feet which hold
it.

The other figure on the right hand represents the dwelling of another
Housebuilder caterpillar. It looks very much as if it were made of
drab cloth. The most remarkable point about it is the lower end. When
the insect is within the dwelling the extremity has a spiral twist,
but when the moth has escaped the spiral form is destroyed, and it
appears as represented in the illustration. The female Oiketicus never
attains the winged state nor leaves her house, but lives and dies in
it, almost unchanged in shape. In fact, the adult female is even more
undeveloped in appearance than the caterpillar, and looks like a large,
fat, unwieldy grub, covered with down. The male, on the contrary, is
a tolerably active moth, with sharply-pointed wings and beautiful
feathered antennae.

Another kind of Housebuilder's residence is shown in the lower
left-hand figure, enveloped and almost concealed by leaves.

The remaining figures represent the dwellings of two unknown insects,
both from Australia. The upper left-hand nest is made wonderfully like
that of the weaver-bird, being composed of fibres like cow-hairs woven
loosely together. It is brown outside and white in the interior.

The last nest is made of some substance which is smooth, and hard as
horn, brown within, and dark grey on the outside. The circular lid by
which the enclosed insect escapes is shown open.

In the accompanying illustration, we have five remarkable pensile nests
of insects, some British, and others exotic.

Fig. 1 represents the nest of a Pelopaeus from Natal. It is made of
dried cow-dung, and is fixed to straws. The length is from three to
five inches, and there are sometimes found three or more in a row upon
a single straw. The insect is about an inch in length, black-blue in
colour, and with clouded wings. The abdomen is small, sharply pointed,
and placed on a long footstalk.

[Illustration: Nests of Pelopaeus (1, 2); Anthidium (3); Trypoxylon (4);
and Eumenes (5).]

At Fig. 2 is seen the nest of _Pelopaeus Flavipes_, a North American
insect, which is also fixed along its whole length to the supporting
object, which is sometimes a wall, and sometimes, as in the
illustration, a branch. It is made of mud, and the insects seem to have
a sort of gregarious instinct, loving to fix their nests in rows, one
above the other. There is only one larva in each cell. The Pelopaei are,
by the way, allied to the English genus _Ammophila_.

Fig. 3 shows the nest of _Anthidium cordatum_, one of the solitary bees
of Natal. It is made of vegetable fibres. The insect as well as the
nest is represented of the natural size. It is black and shining, with
the under part and sides and legs yellowish.

At Fig. 4 are seen three of the nests of _Trypoxylon aurifrons_, a
Brazilian insect. They are built of mud, and are remarkable for their
elegant shape, which looks as if it had been formed by the hand of the
potter, and for the manner in which the mouth is turned over so as to
form a distinct neck. The larvae is fed with a store of spiders. The
insect is represented of the natural size; its colour is black, and the
face is covered with short golden hairs, a fact which has gained for it
the name of aurifrons, or golden-fronted.

Our last example, Fig. 5, is the nest of an English insect, _Eumenes
coarctata_. The insect is represented of its natural size. It is very
pretty in colour as well as elegant in shape, being black, diversified
with yellow bands and spots. The nest is made of clay, and is found
upon the heath twigs. The larvae of the Eumenes are fed with those of
a species of _Crambus_. The insect is tolerably common in Surrey and
Hampshire, and appears in July and August.

The three figures in the next illustration represent the cocoons of
three species of the Bombycidae, and are given in order to show the
different modes by which they are fastened. The upper nest is hung by a
slight cord, which spreads into a broad silken band wrapped round the
branch for some distance. The right-hand figure shows a very remarkable
cocoon suspended by a long footstalk affixed to a ring. The remarkable
point in the construction of this ring is that it is very hard and
horny, and is not fastened to the branch, but passes loosely round it,
so that the cocoon swings backwards and forwards in the breeze. The
cocoon is about two inches in length, and is covered with thick black
veinings. The lowermost cocoon is most curiously fixed to the branch by
bending the leaves round the exterior of the dwelling, and fixing them
to it with silk. All these specimens were brought from Northern India.]

[Illustration: Bombycidae.]

In all the nests of social caterpillars, care is taken to leave
apertures for passing out and in. It is remarkable, also, that however
far they may ramble from their nest, they never fail to find their way
back when a shower of rain or nightfall renders shelter necessary. It
requires no great shrewdness to discover how they effect this: for by
looking closely at their track it will be found that it is carpeted
with silk--no individual moving an inch without constructing such a
pathway, both for the use of his companions and to facilitate his own
return. All these social caterpillars, therefore, move more or less
in processional order, each following the road which the first chance
traveller has marked out with his strip of silk carpeting.

[Illustration: Nest and order of marching of the Processionary
Caterpillars of the oak (_Cnethocampa processionea_).]

There are some species, however, which are more remarkable than others
in the regularity of their processional marchings, particularly two
which are found in the south of Europe, but are not indigenous in
Britain. The one named by Reaumur the Processionary (_Cnethocampa
processionea_, Stephens) feeds upon the oak; a brood dividing, when
newly hatched, into one or more parties of several hundred individuals,
which afterwards unite in constructing a common nest nearly two feet
long, and from four to six inches in diameter. As it is not divided
like that of the brown-tails into chambers, but consists of one large
hall, it is not necessary that there should be more openings than one;
and accordingly, when an individual goes out and carpets a path, the
whole colony instinctively follow in the same track, though from the
immense population they are often compelled to march in parallel files
from two to six deep. The procession is always headed by a single
caterpillar; sometimes the leader is immediately followed by one or
two in single file, and sometimes by two abreast, as represented
in the cut. A similar procedure is followed by a species of social
caterpillars which feed on the pine in Savoy and Languedoc; and though
their nests are not half the size of the preceding, they are more
worthy of notice, from the strong and excellent quality of their silk,
which Reaumur was of opinion might be advantageously manufactured.
Their nest consists of more chambers than one, but is furnished with
a main entrance, through which the colonists conduct their foraging
processions.

[In the accompanying illustration is shown a nest of the Processionary
caterpillar, part of which has been torn away to show the interior.
Inside may be seen the larva of a certain beetle (_Calosoma
sycophanta_), which feeds on these caterpillars, and one of the beetles
is seen below in the act of ascending the tree. This beetle, although
exceedingly scarce in England, is very common on the Continent, and
trees have been cleared of Processionary caterpillars by the simple
process of putting a few female beetles upon the branches.]

[Illustration: Nest of Processionary Caterpillars (_Cnethocampa_ and
_Calosoma_).]




_CHAPTER XVIII._

STRUCTURES OF SPIDERS.


Modern naturalists do not rank spiders among insects, because they have
no antennae, and no division between the head and the shoulders. They
breathe by leaf-shaped gills, situated under the belly, instead of
spiracles in the sides; have a heart connected with these; have eight
legs instead of six; and eight fixed eyes. But as spiders are popularly
considered insects, it will sufficiently suit our purpose to introduce
them here as such.

The apparatus by which spiders construct their ingenious fabrics is
much more complicated than that which we have described as common
to the various species of caterpillars. Caterpillars have only two
reservoirs for the materials of their silk; but spiders, according to
the dissections of M. Treviranus, have four principal vessels, two
larger and two smaller, with a number of minute ones at their base.
Several small tubes branch towards the reservoirs, for carrying to
them, no doubt, a supply of the secreted material. Swammerdam describes
them as twisted into many coils of an agate colour.[EJ] We do not find
them coiled, but nearly straight, and of a deep-yellow colour. From
these, when broken, threads can be drawn out like those spun by the
spider, though we cannot draw them so fine by many degrees.

From these little flasks or bags of gum, situated near the apex of the
abdomen, and not at the mouth, as in caterpillars, a tube originates,
and terminates in the external spinnerets, which may be seen by the
naked eye in the larger spiders, in the form of five little teats
surrounded by a circle, as represented in the following figure.

[Illustration: Garden Spider (_Epeira diadema_), suspended by a thread
proceeding from its spinneret.]

We have seen that the silken thread of a caterpillar is composed
of two united within the tube of the spinneret, but the spider's
thread would appear, from the first view of its five spinnerets, to
be quintuple, and in some species which have six teats, so many times
more. It is not safe, however, in our interpretations of nature to
proceed upon conjecture, however plausible, nor to take anything for
granted which we have not actually seen; since our inferences in such
cases are almost certain to be erroneous. If Aristotle, for example,
had ever looked narrowly at a spider when spinning, he could not have
fancied, as he does, that the materials which it uses are nothing but
wool stripped from its body. On looking, then, with a strong magnifying
glass, at the teat-shaped spinnerets of a spider, we perceive them
studded with regular rows of minute bristle-like points, about a
thousand to each teat, making in all from five to six thousand. These
are minute tubes which we may appropriately term _spinnerules_, as
each is connected with the internal reservoirs, and emits a thread
of inconceivable fineness. In the following figure, this wonderful
apparatus is represented as it appears in the microscope.

[Illustration: Spinnerets of a Spider magnified to show the
_Spinnerules_.]

We do not recollect that naturalists have ventured to assign any cause
for this very remarkable multiplicity of the spinnerules of spiders, so
different from the simple spinneret of caterpillars. To us it appears
to be an admirable provision for their mode of life. Caterpillars
neither require such strong materials, nor that their thread should
dry as quickly. It is well known in our manufactures, particularly
in rope-spinning, that in cords of equal thickness, those which are
composed of many smaller ones united are greatly stronger than those
which are spun at once. In the instance of the spider's thread, this
principle must hold still more strikingly, inasmuch as it is composed
of fluid materials that require to be dried rapidly, and this drying
must be greatly facilitated by exposing so many to the air separately
before their union, which is effected at the distance of about a tenth
of an inch from the spinnerets. In the following figure each of the
threads represented is reckoned to contain one hundred minute threads,
the whole forming only one of the spider's common threads.

Leeuwenhoeck, in one of his extraordinary microscopical observations on
a young spider not bigger than a grain of sand, upon enumerating the
threadlets in one of its threads, calculated that it would require
four millions of them to be as thick as a hair of his beard.

[Illustration: A single thread of a Spider, greatly magnified, so that,
for the small space represented, the lines are shown as parallel.]

[Illustration: Attached end of a Spider's thread magnified.]

Another important advantage derived by the spider from the multiplicity
of its threadlets is, that the thread affords a much more secure
attachment to a wall, a branch of a tree, or any other object, than if
it were simple; for, upon pressing the spinneret against the object, as
spiders always do when they fix a thread, the spinnerules are extended
over an area of some diameter, from every hair's-breadth of which a
_strand_, as rope-makers term it, is extended to compound the main
cord. The preceding figure exhibits this ingenious contrivance.

Those who may be curious to examine this contrivance will see it best
when the line is attached to any black object, for the threads, being
whitish, are, in other cases, not so easily perceived.


Shooting of the Lines.

It has long been considered a curious though a difficult investigation,
to determine in what manner spiders, seeing that they are destitute
of wings, transport themselves from tree to tree, across brooks, and
frequently through the air itself, without any apparent starting point.
On looking into the authors who have treated upon this subject, it is
surprising how little there is to be met with that is new, even in the
most recent. Their conclusions, or rather their conjectural opinions,
are, however, worthy of notice; for by unlearning error, we the more
firmly establish truth.

1. One of the earliest notions upon this subject is that of Blancanus,
the commentator on Aristotle, which is partly adopted by Redi, by
Henricus Regius of Utrecht, by Swammerdam,[EK] by Lehmann, and by Kirby
and Spence.[EL] "The spider's thread," says Swammerdam, "is generally
made up of two or more parts, and after descending by such a thread,
it ascends by one only, and is thus enabled to waft itself from one
height or tree to another, even across running waters; the thread it
leaves loose behind it being driven about by the wind, and so fixed
to some other body." "I placed," says Kirby, "the large garden spider
(_Epeira diadema_) upon a stick about a foot long, set upright in a
vessel containing water.... It let itself drop, not by a single thread,
but by _two_, each distant from the other about the twelfth of an
inch, guided, as usual, by one of its hind feet, and one apparently
smaller than the other. When it had suffered itself to descend nearly
to the surface of the water, it stopped short, and by some means, which
I could not distinctly see, broke off, close to the spinners, the
smallest thread, which still adhering by the other end to the top of
the stick, floated in the air, and was so light as to be carried about
by the slightest breath. On approaching a pencil to the loose end of
this line, it did not adhere from mere contact. I therefore twisted it
once or twice round the pencil, and then drew it tight. The spider,
which had previously climbed to the top of the stick, immediately
pulled at it with one of its feet, and finding it sufficiently tense,
crept along it, strengthening it as it proceeded by another thread, and
thus reached the pencil."

We have repeatedly witnessed this occurrence, both in the fields and
when spiders were placed for experiment, as Kirby has described;
but we very much doubt that the thread broken is ever intended as a
bridge cable, or that it would have been so used in that instance, had
it not been artificially fixed and accidentally found again by the
spider. According to our observations, a spider never abandons, for an
instant, the thread which she despatches in quest of an attachment,
but uniformly keeps trying it with her feet, in order to ascertain its
success. We are, therefore, persuaded that when a thread is broken in
the manner above described, it is because it has been spun too weak;
and spiders may often be seen breaking such threads in the process of
netting their webs. (J. R.)

The plan, besides, as explained by these distinguished writers, would
more frequently prove abortive than successful, from the cut thread
not being sufficiently long. They admit, indeed, that spiders' lines
are often found "a yard or two long, fastened to twigs of grass not a
foot in height.... Here, therefore, some other process must have been
used."[EM]

2. Our celebrated English naturalist, Dr. Lister, whose treatise upon
our native spiders has been the basis of every subsequent work on the
subject, maintains that "some spiders shoot out their threads in the
same manner that porcupines do their quills;[EN] that whereas the
quills of the latter are entirely separated from their bodies, when
thus shot out, the threads of the former remain fixed to their anus,
as the sun's rays to its body."[EO] A French periodical writer goes a
little farther, and says, that spiders have the power of shooting out
threads, and directing them at pleasure towards a determined point,
judging of the distance and position of the object by some sense of
which we are ignorant.[EP] Kirby also says, that he once observed a
small garden spider (_Aranea reticulata_) "standing midway on a long
perpendicular fixed thread, and an appearance caught" his "eye, of
what seemed to be the emission of threads." "I, therefore," he adds,
"moved my arm in the direction in which they apparently proceeded,
and, as I had suspected, a floating thread attached itself to my coat,
along which the spider crept. As this was connected with the spinners
of the spider, it could not have been formed" by breaking a "secondary
thread."[EQ] Again, in speaking of the gossamer-spider, he says, "it
first extends its thigh, shank, and foot, into a right line, and then,
elevating its abdomen till it becomes vertical, _shoots its thread_
into the air, and flies off from its station."[ER]

Another distinguished naturalist, Mr. White of Selborne, in speaking
of the gossamer-spider, says, "Every day in fine weather in autumn do
I see these spiders shooting out their webs, and mounting aloft: they
will go off from the finger, if you will take them into your hand.
Last summer, one alighted on my book as I was reading in the parlour;
and running to the top of the page, and _shooting out a web_, took its
departure from thence. But what I most wondered at was, that it went
off with considerable velocity in a place where no air was stirring;
and I am sure I did not assist it with my breath."[ES]

Having so often witnessed the thread set afloat in the air by
spiders, we can readily conceive the way in which those eminent
naturalists were led to suppose it to be ejected by some animal
force acting like a syringe; but as the statement can be completely
disproved by experiment, we shall only at present ask, in the words of
Swammerdam--"how can it be possible that a thread so fine and slender
should be shot out with force enough to divide and pass through the
air?--is it not rather probable that the air would stop its progress,
and so entangle it and fit it to perplex the spider's operations?"[ET]
The opinion, indeed, is equally improbable with another, suggested by
Dr. Lister, that the spider can retract her thread within the abdomen,
after it has been emitted.[EU] De Geer[EV] very justly joins Swammerdam
in rejecting both of these fancies, which, in our own earlier
observations upon spiders, certainly struck us as plausible and true.
There can be no doubt, indeed, that the animal has a voluntary power of
permitting the material to escape, or stopping it at pleasure, but this
power is not projectile.

3. "There are many people," says the Abbe de la Pluche, "who believe
that the spider flies when they see her pass from branch to branch,
and even from one high tree to another; but she transports herself
in this manner: she places herself upon the end of a branch, or some
projecting body, and there fastens her thread; after which, with her
two hind feet, she squeezes her dugs (_spinnerets_), and presses out
one or more threads of two or three ells in length, which she leaves
to float in the air till it be fixed to some particular place."[EW]
Without pretending to have observed this, Swammerdam says, "I can
easily comprehend how spiders, without giving themselves any motion,
may, by only compressing their spinnerets, force out a thread, which
being driven by the wind, may serve to waft them from one place to
another."[EX] Others, proceeding upon a similar notion, give a rather
different account of the matter. "The spider," says Bingley, "fixes one
end of a thread to the place where she stands, and then with her hind
paws draws out several other threads from the nipples, which, being
lengthened out and driven by the wind to some neighbouring tree or
other object, are by their natural clamminess fixed to it."[EY]

Observation gives some plausibility to the latter opinion, as the
spider always actively uses her legs, though not to draw out the
thread, but to ascertain whether it has caught upon any object. The
notion of her pressing the spinneret with her feet must be a mere
fancy; at least it is not countenanced by anything which we have
observed.

4. An opinion much more recondite is mentioned, if it was not started,
by M. D'Isjonval, that the floating of the spider's thread is
electrical. "Frogs, cats, and other animals," he says, "are affected
by natural electricity, and feel the change of weather; but no other
animal more than myself and my spiders." During wet and windy weather
he accordingly found that they spun very short lines, "but when a
spider spins a long thread, there is a certainty of fine weather for
at least ten or twelve days afterwards."[EZ] A periodical writer, who
signs himself Carolan,[FA] fancies that in darting out her thread the
spider emits a stream of air, or some subtle electric fluid, by which
she guides it as if by magic.

A living writer (Mr. John Murray), whose learning and skill in
conducting experiments give no little weight to his opinions, has
carried these views considerably farther. "The aeronautic spider," he
says, "can propel its thread both horizontally and vertically, and at
all relative angles, in motionless air, and in an atmosphere agitated
by winds; nay more, the aerial traveller can even dart its thread, to
use a nautical phrase, in the 'wind's eye.' My opinion and observations
are based on many hundred experiments.... The entire phenomena are
electrical. When a thread is propelled in a vertical plane, it remains
perpendicular to the horizontal plane, always upright, and when others
are projected at angles more or less inclined, their direction is
invariably preserved; the threads never intermingle, and when a pencil
of threads is propelled, it ever presents the appearance of a divergent
brush. These are electrical phenomena, and cannot be explained but on
electrical principles."

"In clear, fine weather, the air is invariably positive; and it is
precisely in such weather that the aeronautic spider makes its ascent
most easily and rapidly, whether it be in summer or in winter." "When
the air is weakly positive, the ascent of the spider will be difficult,
and its altitude extremely limited, and the threads propelled will
be but little elevated above the horizontal plane. When negative
electricity prevails, as in cloudy weather, or on the approach of rain,
and the index of De Saussure's hygrometer rapidly advancing towards
humidity, the spider is unable to ascend."[FB]

Mr. Murray had previously told us, that "when a stick of excited
sealing-wax is brought near the thread of suspension, it is evidently
repelled; consequently, the electricity of the thread is of a negative
character," while "an excited glass tube brought near, seemed to
attract the thread, and with it the aeronautic spider."[FC] His friend,
Mr. Bowman, further describes the aerial spider as "shooting out four
or five, often six or eight, extremely fine webs several yards long,
which waved in the breeze, diverging from each other like a pencil of
rays." One of them "had two distinct and widely-diverging fasciculi of
webs," and "a line uniting them would have been at right angles to the
direction of the breeze."[FD]

Such is the chief evidence in support of the electrical theory; but
though we have tried these experiments, we have not succeeded in
verifying any one of them. The following statements of Mr. Blackwall
come nearer our own observations.

5. "Having procured a small branched twig," says Mr. Blackwall, "I
fixed it upright in an earthen vessel containing water, its base being
immersed in the liquid, and upon it I placed several of the spiders
which produce gossamer. Whenever the insects thus circumstanced were
exposed to a current of air, either naturally or artificially produced,
they directly turned the thorax towards the quarter whence it came,
even when it was so slight as scarcely to be perceptible, and elevating
the abdomen, they emitted from their spinners a small portion of
glutinous matter, which was instantly carried out in a line, consisting
of four finer ones, with a velocity equal, or nearly so, to that with
which the air moved, as was apparent from observations made on the
motion of detached lines similarly exposed. The spiders, in the next
place, carefully ascertained whether their lines had become firmly
attached to any object or not, by pulling at them with the first pair
of legs; and if the result was satisfactory, after tightening them
sufficiently, they made them pass to the twig; then discharging from
their spinners, which they applied to the spot where they stood, a
little more of their liquid gum, and committing themselves to these
bridges of their own constructing, they passed over them in safety,
drawing a second line after them, as a security in case the first gave
way, and so effected their escape.

"Such was invariably the result when spiders were placed where the air
was liable to be sensibly agitated: I resolved, therefore, to put a
bell-glass over them; and in this situation they remained seventeen
days, evidently unable to produce a single line by which they could
quit the branch they occupied, without encountering the water at its
base; though, on the removal of the glass, they regained their liberty
with as much celerity as in the instances already recorded.

"This experiment, which, from want of due precaution, has misled so
many distinguished naturalists, I have tried with several geometric
spiders, and always with the same success."[FE]

Mr. Blackwall, from subsequent experiments, says he is "confident
in affirming, that in motionless air spiders have not the power of
darting their threads even through the space of half an inch."[FF]
The following details are given in confirmation of this opinion. Mr.
Blackwall observed, the 1st Oct., 1826, a little before noon, with the
sun shining brightly, no wind stirring, and the thermometer in the
shade ranging from 55 deg.5 to 64 deg., a profusion of shining lines crossing
each other at every angle, forming a confused net-work, covering
the fields and hedges, and thickly coating his feet and ankles, as
he walked across a pasture. He was more struck with the phenomenon,
because on the previous day a strong gale of wind had blown from the
south, and as gossamer is only seen in calm weather, it must have been
all produced within a very short time.

"What more particularly arrested my attention," says Mr. Blackwall,
"was the ascent of an amazing quantity of webs, of an irregular,
complicated structure, resembling ravelled silk of the finest quality
and clearest white; they were of various shapes and dimensions, some of
the largest measuring upwards of a yard in length, and several inches
in breadth in the widest part; while others were almost as broad as
long, presenting an area of a few square inches only.

"These webs, it was quickly perceived, were not formed in the air, as
is generally believed, but at the earth's surface. The lines of which
they were composed, being brought into contact by the mechanical action
of gentle airs, adhered together, till, by continual additions, they
were accumulated into flakes or masses of considerable magnitude, on
which the ascending current, occasioned by the rarefaction of the
air contiguous to the heated ground, acted with so much force as to
separate them from the objects to which they were attached, raising
them in the atmosphere to a perpendicular height of at least several
hundred feet. I collected a number of these webs about mid-day, as they
rose; and again in the afternoon, when the upward current had ceased,
and they were falling; but scarcely one in twenty contained a spider:
though, on minute inspection, I found small winged insects, chiefly
aphides, entangled in most of them.

"From contemplating this unusual display of gossamer, my thoughts were
naturally directed to the animals which produced it, and the countless
myriads in which they swarmed almost created as much surprise as the
singular occupation that engrossed them. Apparently actuated by the
same impulse, all were intent upon traversing the regions of air:
accordingly, after gaining the summits of various objects, as blades of
grass, stubble, rails, gates, &c., by the slow and laborious process
of climbing, they raised themselves still higher by straightening
their limbs; and elevating the abdomen, by bringing it from the usual
horizontal position into one almost perpendicular, they emitted from
their spinning apparatus a small quantity of the glutinous secretion
with which they construct their webs. This viscous substance being
drawn out by the ascending current of rarefied air into fine lines
several feet in length, was carried upward, until the spiders, feeling
themselves acted upon with sufficient force in that direction, quitted
their hold of the objects on which they stood, and commenced their
journey by mounting aloft.

"Whenever the lines became inadequate to the purpose for which they
were intended, by adhering to any fixed body, they were immediately
detached from the spinners, and so converted into terrestrial gossamer,
by means of the last pair of legs, and the proceedings just described
were repeated; which plainly proves that these operations result from
a strong desire felt by the insects to effect an ascent."[FG] Mr.
Blackwall has recently read a paper (still unpublished) in the Linnean
Society, confirmatory of his opinions.

6. Without going into the particulars of what agrees or disagrees
in the above experiments with our own observations, we shall give a
brief account of what we have actually seen in our researches. (J.
R.) So far as we have determined, then, all the various species of
spiders, how different soever the form of their webs may be, proceed
in the circumstance of shooting their lines precisely alike; but
those which we have found the most manageable in experimenting, are
the small gossamer spider (_Aranea obtextrix_, Bechstein), known by
its shining blackish-brown body and reddish-brown semi-transparent
legs; but particularly the long-bodied spider (_Tetragnatha extensa_,
Latr.), which varies in colour from green to brownish or grey--but has
always a black line along the belly, with a silvery white or yellowish
one on each side. The latter is chiefly recommended by being a very
industrious and persevering spinner, while its movements are easily
seen, from the long cylindrical form of its body and the length of its
legs.

We placed the above two species with five or six others, including
the garden, the domestic and the labyrinthic spiders, in empty
wine-glasses, set in tea-saucers filled with water to prevent their
escape. When they discovered, by repeated descents from the brims of
the glasses, that they were thus surrounded by a wet ditch, they all
set themselves to the task of throwing their silken bridges across. For
this purpose they first endeavoured to ascertain in what direction the
wind blew, or rather (as the experiment was made in our study) which
way any current of air set,--by elevating their arms as we have seen
sailors do in a dead calm. But, as it may prove more interesting to
keep to one individual, we shall first watch the proceedings of the
gossamer spider.

Finding no current of air on any quarter of the brim of the glass, it
seemed to give up all hopes of constructing its bridge of escape, and
placed itself in the attitude of repose; but no sooner did we produce
a stream of air, by blowing gently towards its position, than, fixing
a thread to the glass, and laying hold of it with one of its feet, by
way of security, it placed its body in a vertical position, with its
spinnerets extended outwards; and immediately we had the pleasure of
seeing a thread streaming out from them several feet in length, on
which the little aeronaut sprung up into the air. We were convinced,
from what we thus observed, that it was the double or bend of the
thread which was blown into the air; and we assigned as a reason for
her previously attaching and drawing out a thread from the glass, the
wish to give the wind a _point d'appui_--something upon which it might
have a _purchase_, as a mechanic would say of a lever. The bend of the
thread, then, on this view of the matter, would be carried out by the
wind,--would form the point of impulsion,--and, of course, the escape
bridge would be an ordinary line doubled.

Such was our conclusion, which was strongly corroborated by what we
subsequently found said by M. Latreille--than whom no higher authority
could be given. "When the animal," says he, "desires to cross a brook,
she fixes to a tree or some other object one of the ends of her first
threads, in order that the wind or a current of air may carry the other
end beyond the obstacle;"[FH] and as one end is always attached to the
spinnerets, he must mean that the double of the thread flies off. In
his previous publications, however, Latreille had contented himself
with copying the statement of Dr. Lister.

In order to ascertain the fact, and put an end to all doubts, we
watched, with great care and minuteness, the proceedings of the
long-bodied spider above mentioned, by producing a stream of air
in the same manner, as it perambulated the brim of the glass. It
immediately, as the other had done, attached a thread, and raised
its body perpendicularly, like a tumbler, standing on his hands with
his head downwards; but we looked in vain for this thread bending,
as we had at first supposed, and going off double. Instead of this
it remained tight, while another thread, or what appeared to be so,
streamed off from the spinners, similar to smoke issuing through a
pin-hole, sometimes in a line, and sometimes at a considerable angle,
with the first, according to the current of the air,--the first thread,
extended from the glass to the spinnerets, remaining all the while
tight drawn in a right line. It further appeared to us, that the
first thread proceeded from the pair of spinnerets nearest the head,
while the floating thread came from the outer pair,--though it is
possible in such minute objects we may have been deceived. That the
first was continuous with the second, without any perceptible joining,
we ascertained in numerous instances, by catching the floating line
and pulling it tight, in which case the spider glides along without
attaching another line to the glass; but if she has to coil up the
floating line to tighten it, as usually happens, she gathers it into
a packet and glues the two ends tight together. Her body, while
the floating line streamed out, remained quite motionless, but we
distinctly saw the spinnerets not only projected, as is always done
when a spider spins, but moved in the same way as an infant moves its
lips when sucking. We cannot doubt, therefore, that this motion is
intended to emit (if _eject_ or _project_ be deemed too strong words)
the liquid material of the thread; at the same time, we are quite
certain that it cannot throw out a single inch of thread without the
aid of a current of air. A long-bodied spider will thus throw out in
succession as many threads as we please, by simply blowing towards it;
but not one where there is no current, as under a bell-glass, where it
may be kept till it die, without being able to construct a bridge over
water of an inch long. We never observed more than one floating thread
produced at the same time; though other observers mention several.

The probable commencement, we think, of the floating line, is by the
emission of little globules of the glutinous material to the points of
the spinnerules--perhaps it may be dropped from them, if not ejected,
and the globules being carried off by the current of air, drawn out
into a thread. But we give this as only a conjecture, for we could not
bring a glass of sufficient power to bear upon the spinnerules at the
commencement of the floating line.

In subsequent experiments we found that it was not indispensable for
the spider to rest upon a solid body when producing a line, as she can
do so while she is suspended in the air by another line. When the
current of air also is strong, she will sometimes commit herself to it
by swinging from the end of the line. We have even remarked this when
there was scarcely a breath of air.

We tried another experiment. We pressed pretty firmly upon the base of
the spinnerets, so as not to injure the spider, blowing obliquely over
them; but no floating line appeared. We then touched them with a pencil
and drew out several lines an inch or two in length, upon which we blew
in order to extend them; but in this also we were unsuccessful, as they
did not lengthen more than a quarter of an inch. We next traced out
the reservoirs of a garden-spider (_Epeira diadema_), and immediately
taking a drop of the matter from one of them on the point of a fine
needle, we directed upon it a strong current of air, and succeeded in
blowing out a thick yellow line, as we might have done with gum-water,
of about an inch and a half long.

When we observed our long-bodied spider eager to throw a line by
raising up its body, we brought within three inches of its spinnerets
an excited stick of sealing-wax, of which it took no notice, nor did
any thread extend to it, not even when brought almost to touch the
spinnerets. We had the same want of success with an excited glass rod;
and indeed we had not anticipated any other result, as we have never
observed that these either attract or repel the floating threads,
as Mr. Murray has seen them do; nor have we ever seen the end of a
floating thread separated into its component threadlets and diverging
like a brush, as he and Mr. Bowman describe. It may be proper to
mention that Mr. Murray, in conformity with his theory, explains the
shooting of lines in a current of air by the electric state produced by
motion in consequence of the mutual friction of the gaseous particles.
But this view of the matter does not seem to affect our statements.


Nests, Webs, and Nets of Spiders.

The neatest, though the smallest spider's nest which we have seen, was
constructed in the chink of a garden post, which we had cut out in
the previous summer in getting at the cells of a carpenter-bee. The
architect was one of the large hunting-spiders, erroneously said by
some naturalists to be incapable of spinning. The nest in question was
about two inches high, composed of a very close satin-like texture.
There were two parallel chambers placed perpendicularly, in which
position also the inhabitant reposed there during the day, going, as we
presume, only abroad to prey during the night. But the most remarkable
circumstance was, that the openings (two above and two below) were so
elastic, that they shut almost as closely as the boat cocoon of the
_Tortrix Chlorana_. We observed this spider for several months, but at
last it disappeared, and we took the nest out, under the notion that
it might contain eggs; but we found none, and therefore conclude that
it was only used as a day retreat. (J. R.) The account which Evelyn
has given of these hunting-spiders is so interesting, that we must
transcribe it.

"Of all sorts of insects," says he, "there is none has afforded me
more divertisement than the _venatores_ (hunters), which are a sort of
_lupi_ (wolves) that have their dens in rugged walls and crevices of
our houses; a small brown and delicately-spotted kind of spiders, whose
hinder legs are longer than the rest. Such I did frequently observe
at Rome, which, espying a fly at three or four yards' distance, upon
the balcony where I stood, would not make directly to her, but crawl
under the rail till, being arrived at the antipodes, it would steal
up, seldom missing its aim; but if it chanced to want anything of
being perfectly opposite, would, at first peep, immediately slide down
again,--till, taking better notice, it would come the next time exactly
upon the fly's back: but if this happened not to be within a competent
leap, then would this insect move so softly, as the very shadow of the
gnomon seemed not to be more imperceptible, unless the fly moved; and
then would the spider move also in the same proportion, keeping that
just time with her motion, as if the same soul had animated both these
little bodies; and whether it were forwards, backwards, or to either
side, without at all turning her body like a well-managed horse: but
if the capricious fly took wing and pitched upon another place behind
our huntress, then would the spider whirl its body so nimbly about, as
nothing could be imagined more swift: by which means she always kept
the head towards her prey, though, to appearance, as immovable as if
it had been a nail driven into the wood, till by that indiscernible
progress (being arrived within the sphere of her reach) she made a
fatal leap, swift as lightning, upon the fly, catching him in the pole,
where she never quitted hold till her belly was full, and then carried
the remainder home."

One feels a little sceptical, however, when he adds, "I have beheld
them instructing their young ones how to hunt, which they would
sometimes discipline for not well observing; but when any of the old
ones did (as sometimes) miss a leap, they would run out of the field
and hide themselves in their crannies, as ashamed, and haply not
to be seen abroad for four or five hours after; for so long have I
watched the nature of this strange insect, the contemplation of whose
so wonderful sagacity and address has amazed me; nor do I find in any
chase whatsoever more cunning and stratagem observed. I have found some
of these spiders in my garden, when the weather, towards spring, is
very hot, but they are nothing so eager in hunting as in Italy."[FI]

We have only to add to this lively narrative, that the hunting-spider,
when he leaps, takes good care to provide against accidental falls by
always swinging himself from a good strong cable of silk, as Swammerdam
correctly states,[FJ] and which anybody may verify, as one of the
small hunters (_Salticus scenicus_), known by having its back striped
with black and white like a zebra, is very common in Britain.

Mr. Weston, the editor of 'Bloomfield's Remains,' falls into a
very singular mistake about hunting-spiders, imagining them to be
web-weaving ones which have exhausted their materials, and which are
therefore compelled to hunt. In proof of this he gives an instance
which fell under his own observation![FK]

As a contrast to the little elastic satin nest of the hunter, we
may mention the largest with which we are acquainted,--that of the
labyrinthic spider (_Agelena labyrinthica_, Walchenaer). Our readers
must often have seen this nest spread out like a broad sheet in hedges,
furze, and other low bushes, and sometimes on the ground. The middle
of this sheet, which is of a close texture, is swung like a sailor's
hammock, by silken ropes extended all around to the higher branches;
but the whole curves upwards and backwards, sloping down to a long
funnel-shaped gallery which is nearly horizontal at the entrance, but
soon winds obliquely till it becomes quite perpendicular. This curved
gallery is about a quarter of an inch in diameter, is much more closely
woven than the sheet part of the web, and sometimes descends into a
hole in the ground, though oftener into a group of crowded twigs, or a
tuft of grass. Here the spider dwells secure, frequently resting with
her legs extended from the entrance of the gallery, ready to spring out
upon whatever insect may fall into her sheet net. She herself can only
be caught by getting behind her and forcing her out into the web; but
though we have often endeavoured to make her construct a nest under our
eye, we have been as unsuccessful as in similar experiments with the
common house spider (_Aranea domestica_). (J. R.)

The house spider's proceedings were long ago described by Homberg,
and the account has been copied, as usual, by almost every subsequent
writer. Goldsmith has, indeed, given some strange misstatements from
his own observations, and Bingley has added the original remark, that,
after fixing its first thread, creeping along the wall, and joining
it as it proceeds, it "_darts itself to the opposite side_, where
the other end is to be fastened!"[FL] Homberg's spider took the more
circuitous route of travelling to the opposite wall, carrying in one
of the claws the end of the thread previously fixed, lest it should
stick in the wrong place. This we believe to be the correct statement,
for as the web is always horizontal, it would seldom answer to commit
a floating thread to the wind, as is done by other species. Homberg's
spider, after stretching as many lines by way of _warp_ as it deemed
sufficient between the two walls of the corner which it had chosen,
proceeded to cross this in the way our weavers do in adding the _woof_,
with this difference, that the spider's threads were only laid on, and
not interlaced.[FM] The domestic spiders, however, in these modern
days, must have forgot this mode of weaving, for none of their webs
will be found to be thus regularly constructed!

The geometric, or net-working spiders (_Tendeuses_, Latr.), are as well
known in most districts as any of the preceding; almost every bush and
tree in the gardens and hedge-rows having one or more of their nets
stretched out in a vertical position between adjacent branches. The
common garden spider (_Epeira diadema_), and the long-bodied spider
(_Tetragnatha extensa_), are the best known of this order.

The chief care of a spider of this sort is, to form a cable of
sufficient strength to bear the net she means to hang upon it; and,
after throwing out a floating line as above described, when it catches
properly she doubles and redoubles it with additional threads. On
trying its strength she is not contented with the test of pulling it
with her legs, but drops herself down several feet from various points
of it, as we have often seen, swinging and bobbing with the whole
weight of her body. She proceeds in a similar manner with the rest of
the framework of her wheel-shaped net; and it may be remarked that some
of the ends of these lines are not simple, but in form of a Y, giving
her the additional security of two attachments instead of one.

[Illustration: Geometric Net of _Epeira diadema_.]

In constructing the body of the net, the most remarkable circumstance
is her using her limbs as a measure, to regulate the distances of her
_radii_ or wheel-spokes, and the circular meshes interweaved into them.
These are consequently always proportional to the size of the spider.
She often takes up her station in the centre, but not always, though
it is so said by inaccurate writers; for she as frequently lurks in a
little chamber constructed under a leaf or other shelter at the corner
of her web, ready to dart down upon whatever prey may be entangled in
her net. The centre of the net is said also to be composed of more
viscid materials than its suspensory lines,--a circumstance alleged to
be proved by the former appearing under the microscope studded with
globules of gum.[FN] We have not been able to verify this distinction,
having seen the suspensory lines as often studded in this manner as
those in the centre. (J. R.)


Mason-Spiders.

A no less wonderful structure is composed by a sort of spiders,
natives of the tropics and the south of Europe, which have been justly
called mason-spiders by M. Latreille. One of these (_Mygale nidulans_,
Walckn.), found in the West Indies, "digs a hole in the earth obliquely
downwards about three inches in length, and one in diameter. This
cavity she lines with a tough thick web, which, when taken out,
resembles a leathern purse; but, what is most curious, this house has
a door with hinges, like the operculum of some sea-shells, and herself
and family, who tenant this nest, open and shut the door whenever they
pass and repass. This history was told me," says Darwin, "and the nest,
with its door, shown me by the late Dr. Butt, of Bath, who was some
years physician in Jamaica."[FO]

[Illustration: Nest of the Mason-Spider.

A. The nest shut. B. The nest open. C. The spider, _Mygale caementaria_.
D. The eyes magnified. E, F. Parts of the foot and claw magnified.]

The nest of a mason-spider, similar to this, has been obligingly put
into our hands by Mr. Riddle, of Blackheath. It came from the West
Indies, and is probably that of Latreille's clay-kneader (_Mygale
cratiens_), and one of the smallest of the genus. We have since
seen a pair of these spiders in possession of Mr. William Mello, of
Blackheath. The nest is composed of very hard argillaceous clay, deeply
tinged with brown oxide of iron. It is in form of a tube, about one
inch in diameter, between six and seven inches long, and slightly bent
towards the lower extremity--appearing to have been mined into the clay
rather than built. The interior of the tube is lined with a uniform
tapestry of silken web, of an orange-white colour, with a texture
intermediate between India paper and very fine glove leather. But the
most wonderful part of this nest is its entrance, which we look upon
as the perfection of insect architecture. A circular door, about the
size of a crown piece, slightly concave on the outside and convex
within, is formed of more than a dozen layers of the same web which
lines the interior, closely laid upon one another, and shaped so that
the inner layers are the broadest, the outer being gradually less in
diameter, except towards the hinge, which is about an inch long; and in
consequence of all the layers being united there, and prolonged into
the tube, it becomes the thickest and strongest part of the structure.
The elasticity of the materials, also, gives to this hinge the
remarkable peculiarity of acting like a spring, and shutting the door
of the nest spontaneously. It is, besides, made to fit so accurately to
the aperture, which is composed of similar concentric layers of web,
that it is almost impossible to distinguish the joining by the most
careful inspection. To gratify curiosity, the door has been opened and
shut hundreds of times, without in the least destroying the power of
the spring. When the door is shut, it resembles some of the lichens
(_Lecidea_), or the leathery fungi, such as _Polyporus versicolor_
(Micheli), or, nearer still, the upper valve of a young oyster shell.
The door of the nest, the only part seen above ground, being of a
blackish-brown colour, it must be very difficult to discover. (J. R.)

Another mason-spider (_Mygale caementaria_, Latr.), found in the south
of France, usually selects for her nest a place bare of grass, sloping
in such a manner as to carry off the water, and of a firm soil, without
rocks or small stones. She digs a gallery a foot or two in depth, and
of a diameter (equal throughout) sufficient to admit of her easily
passing. She lines this with a tapestry of silk glued to the walls.
The door, which is circular, is constructed of many layers of earth
kneaded, and bound together with silk. Externally, it is flat and
rough, corresponding to the earth around the entrance, for the purpose,
no doubt, of concealment: on the inside it is convex, and tapestried
thickly with a web of fine silk. The threads of this door-tapestry are
prolonged, and strongly attached to the upper side of the entrance,
forming an excellent hinge, which, when pushed open by the spider,
shuts again by its own weight, without the aid of spring hinges. When
the spider is at home, and her door forcibly opened by an intruder, she
pulls it strongly inwards, and even when half-opened often snatches it
out of the hand; but when she is foiled in this, she retreats to the
bottom of her den, as her last resource.[FP]

Rossi ascertained that the female of an allied species (_Mygale
sauvagesii_, Latr.), found in Corsica, lived in one of these nests,
with a numerous posterity. He destroyed one of these doors to observe
whether a new one would be made, which it was; but it was fixed
immovably, without a hinge; the spider, no doubt, fortifying herself in
this manner till she thought she might reopen it without danger.[FQ]

[The accompanying illustration shows one of these nests, which is
in my own collection. It was brought from Jamaica, together with the
spider that made it.

[Illustration]

The nest is nearly six inches in length, and is made of a double layer
of silken web. The inner layer is yellowish, with a tinge of red,
and although fine, very tough and strong. The outer layer is thick,
coarse, dark brown, and rather flaky, the dark colour being probably
caused by the earth which is mixed with it. The lid is made of eight
or ten layers of coarse web, overlapping each other like the tiles of
a house-roof, and the entrance of the nest is formed after the same
fashion. If the lid be opened, the inside of the nest is seen to be
of a different make from the exterior, being greyish-white, smooth,
close-textured, and looking much like the finest kid leather.

[Illustration]

The smaller illustration shows the spider in the act of emerging from
its home.]

       *       *       *       *       *

"The Rev. Revett Shepherd has often noticed, in the fen ditches of
Norfolk, a very large spider (the species not yet determined) which
actually forms a _raft_ for the purpose of obtaining its prey with
more facility. Keeping its station upon a ball of weeds about three
inches in diameter, probably held together by slight silken cords, it
is wafted along the surface of the water upon this floating island,
which it quits the moment it sees a drowning insect. The booty thus
seized it devours at leisure upon its raft, under which it retires when
alarmed by any danger."[FR] In the spring of 1830, we found a spider on
some reeds in the Croydon Canal, which agreed in appearance with Mr.
Shepherd's.

Among our native spiders there are several besides this one, which, not
contented with a web like the rest of their congeners, take advantage
of other materials to construct cells where, "hushed in grim repose,"
they "expect their insect prey." The most simple of those spider-cells
is constructed by a longish-bodied spider (_Aranea holosericea_,
Linn.), which is a little larger than the common hunting-spider. It
rolls up a leaf of the lilac or poplar, precisely in the same manner as
is done by the leaf-rolling caterpillars, upon whose cells it sometimes
seizes to save itself trouble, having first expelled, or perhaps
devoured, the rightful owner. The spider, however, is not satisfied
with the tapestry of the caterpillar, but always weaves a fresh set of
her own, much more close and substantial.

Another spider, common in woods and copses (_Epeira quadrata?_), weaves
together a great number of leaves to form a dwelling for herself, and
in front of it she spreads her toils for entrapping the unwary insects
which stray thither. These, as soon as caught, are dragged into her
den, and stored up for a time of scarcity. Here also her eggs are
deposited and hatched in safety. When the cold weather approaches, and
the leaves of her edifice wither, she abandons it for the more secure
shelter of a hollow tree, where she soon dies; but the continuation of
the species depends upon eggs, deposited in the nest before winter, and
remaining to be hatched with the warmth of the ensuing summer.

The spider's den of united leaves, however, which has just been
described, is not always useless when withered and deserted, for the
dormouse usually selects it as a ready-made roof for its nest of dried
grass. That those old spiders' dens are not accidentally chosen by the
mouse, appears from the fact, that out of about a dozen mouse-nests of
this sort found during winter in a copse between Lewisham and Bromley,
Kent, every second or third one was furnished with such a roof. (J. R.)


Diving Water-Spider.

Though spiders require atmospheric air for respiration, yet one species
well known to naturalists is aquatic in its habits, and lives not
only upon the surface but below the surface of the water, contriving
to carry down with it a sufficiency of air for the support of life
during a considerable period of time. Its subaqueous nest is in fact
a sort of diving-bell, and constitutes a secure and most ingenious
habitation. This spider does not like stagnant water, but prefers low
running streams, canals, and ditches, where she may often be seen in
the vicinity of London and elsewhere, living in her diving-bell, which
shines through the water like a little globe of silver: her singular
economy was first, we believe, described by Clerck,[FS] L. M. de
Lignac,[FT] and De Geer.

"The shining appearance," says Clerck, "proceeds either from an
inflated globule surrounding the abdomen, or from the space between
the body and the water. The spider, when wishing to inhale the air,
rises to the surface, with its body still submersed, and only the part
containing the spinneret rising just to the surface, when it briskly
opens and moves its four teats. A thick coat of hair keeps the water
from approaching or wetting the abdomen. It comes up for air about four
times an hour or oftener, though I have good reason to suppose it can
continue without it for several days together.

"I found in the middle of May one male and ten females, which I put
into a glass filled with water, where they lived together very quietly
for eight days. I put some duckweed (_Lemna_) into the glass to afford
them shelter, and the females began to stretch diagonal threads in
a confused manner from it to the sides of the glass about half-way
down. Each of the females afterwards fixed a close bag to the edge
of the glass, from which the water was expelled by the air from the
spinneret, and thus a cell was formed capable of containing the whole
animal. Here they remained quietly, with their abdomens in their cells,
and their bodies still plunged in the water; and in a short time
brimstone- bags of eggs appeared in each cell, filling it about
a fourth part. On the 7th of July several young ones swam out from one
of the bags. All this time the old ones had nothing to eat, and yet
they never attacked one another as other spiders would have been apt to
do."[FU]

"These spiders," says De Geer, "spin in the water a cell of strong,
closely-woven white silk, in the form of half the shell of a pigeon's
egg, or like a diving-bell. This is sometimes left partly above water,
but at others is entirely submersed, and is always attached to the
objects near it by a great number of irregular threads. It is closed
all round, but has a large opening below, which, however, I found
closed on the 15th of December, and the spider living quietly within,
with her head downwards. I made a rent in this cell, and expelled the
air, upon which the spider came out; yet, though she appeared to have
been laid up for three months in her winter quarters, she greedily
seized upon an insect and sucked it. I also found that the male as well
as the female constructs a similar subaqueous cell, and during summer
no less than in winter."[FV] We have recently kept one of these spiders
for several months in a glass of water, where it built a cell half
under water, in which it laid its eggs.


Cleanliness of Spiders.

When we look at the viscid material with which spiders construct
their lines and webs, and at the rough, hairy covering (with a few
exceptions) of their bodies, we might conclude that they would be
always stuck over with fragments of the minute fibres which they
produce. This, indeed, must often happen, did they not take careful
precautions to avoid it; for we have observed that they seldom, if
ever, leave a thread to float at random, except when they wish to form
a bridge. When a spider drops along a line, for instance, in order to
ascertain the strength of her web, or the nature of the place below
her, she invariably, when she reascends, coils it up into a little
ball, and throws it away. Her claws are admirably adapted for this
purpose, as well as for walking along the lines, as may be readily seen
by a magnifying glass.

[Illustration: Triple-clawed foot of a Spider, magnified.]

There are three claws, one of which acts as a thumb, the others being
toothed like a comb, for gliding along the lines. This structure,
however, unfits it to walk, as flies can do, upon any upright polished
surface like glass; although the contrary[FW] is erroneously asserted
by the Abbe de la Pluche. Before she can do so, she is obliged to
construct a ladder of ropes, as Mr. Blackwell remarks,[FX] by elevating
her spinneret as high as she can, and laying down a step upon which she
stands to form a second, and so on; as any one may try by placing a
spider at the bottom of a very clean wine-glass.

The hairs of the legs, however, are always catching bits of web and
particles of dust; but these are not suffered to remain long. Most
people may have remarked that the house-fly is ever and anon brushing
its feet upon one another to rub off the dust, though we have not seen
it remarked in authors that spiders are equally assiduous in keeping
themselves clean. They have, besides, a very efficient instrument in
their mandibles or jaws, which, like their claws, are furnished with
teeth; and a spider which appears to a careless observer as resting
idly, in nine cases out of ten will be found slowly combing her legs
with her mandibles, beginning as high as possible on the thigh, and
passing down to the claws. The flue which she thus combs off is
regularly tossed away.

With respect to the house-spider (_A. domestica_), we are told in
books, that "she from time to time clears away the dust from her
web, and sweeps the whole by giving it a shake with her paw, so
nicely proportioning the force of her blow, that she never breaks
anything."[FY] That spiders may be seen shaking their webs in this
manner, we readily admit; though it is not, we imagine, to clear them
of dust, but to ascertain whether they are sufficiently sound and
strong.

We recently witnessed a more laborious process of cleaning a web
than merely shaking it. On coming down the Maine by the steamboat
from Frankfort, in August, 1829, we observed the geometric-net of
a conic-spider (_Epeira conica_, Walck.) on the framework of the
deck, and as it was covered with flakes of soot from the smoke of
the engine, we were surprised to see a spider at work on it; for, in
order to be useful, this sort of net must be clean. Upon observing it
a little closely, however, we perceived that she was not constructing
a net, but dressing up an old one; though not, we must think, to save
trouble, so much as an expenditure of material. Some of the lines she
dexterously stripped of the flakes of soot adhering to them; but in
the greater number, finding that she could not get them sufficiently
clean, she broke them quite off, bundled them up, and tossed them over.
We counted five of these packets of rubbish which she thus threw away,
though there must have been many more, as it was some time before we
discovered the manoeuvre, the packets being so small as not to be
readily perceived, except when placed between the eye and the light.
When she had cleared off all the sooty lines, she began to replace them
in the usual way; but the arrival of the boat at Mentz put an end to
our observations. (J. R.) Bloomfield, the poet, having observed the
disappearance of these bits of ravelled web, imagined that the spider
swallowed them; and even says that he observed a garden spider moisten
the pellets before swallowing them![FZ] Dr. Lister, as we have already
seen, thought the spider retracted the threads within the abdomen.




_CHAPTER XIX._

STRUCTURES OF GALL-FLIES AND APHIDES.


Many of the processes which we have detailed bear some resemblance to
our own operations of building with materials cemented together; but
we shall now turn our attention to a class of insect-architects, who
cannot, so far as we know, be matched in prospective skill by any of
the higher orders of animals. We refer to the numerous family which
have received the name of gall-flies,--a family which, as yet, is
very imperfectly understood, their economy being no less difficult to
trace than their species is to arrange in the established systems of
classification; though the latter has been recently much improved by
Mr. Westwood.

[Illustration: Small berry-shaped galls of the oak leaf, produced by
_Cynips quercus folii_?]

One of the most simple and very common instances of the nests
constructed by gall-insects, may be found in abundance during the
summer, on the leaves of the rose-tree, the oak, the poplar, the willow
(_Salix viminalis_), and many other trees, in the globular form of
a berry, about the size of a currant, and usually of a green colour,
tinged with red, like a ripe Alban or Baltimore apple.

When this psuedo-apple in miniature is cut into, it is found to be
fresh, firm, juicy, and hollow in the centre, where there is either
an egg or a grub safely lodged, and protected from all ordinary
accidents. Within this hollow ball the egg is hatched, and the grub
feeds securely on its substance, till it prepares for its winter sleep,
before changing into a gall-fly (_Cynips_) in the ensuing summer. There
is a mystery as to the manner in which this gall-fly contrives to
produce the hollow miniature apples, each enclosing one of her eggs;
and the doubts attendant upon the subject cannot, so far as our present
knowledge extends, be solved, except by plausible conjecture. Our
earlier naturalists were of opinion that it was the grub which produced
the galls, by eating, when newly hatched, through the cuticle of the
leaf, and remaining till the juices flowing from the wound enveloped
it, and acquired consistence by exposure to the air. This opinion,
however, plausible as it appeared to be, was at once disproved by
finding unhatched eggs on opening the galls.

[Illustration: Ovipositor of Gall-fly, greatly magnified.]

There can be no doubt, indeed, that the mother gall-fly makes a hole
in the plant for the purpose of depositing her eggs. She is furnished
with an admirable ovipositor for that express purpose, and Swammerdam
actually saw a gall-fly thus depositing her eggs, and we have recently
witnessed the same in several instances. In some of these insects
the ovipositor is conspicuously long, even when the insect is at
rest; but in others, not above a line or two of it is visible, till
the belly of the insect be gently pressed. When this is done to the
fly that produces the currant-gall of the oak, the ovipositor may be
seen issuing from a sheath in form of a small curved needle, of a
chestnut-brown colour, and of a horny substance, and three times as
long as it at first appeared.

[Illustration: Gall-fly, and mechanism of ovipositor, greatly
magnified.]

What is most remarkable in this ovipositor is, that it is much longer
than the whole body of the insect, in whose belly it is lodged in a
sheath, and, from its horny nature, it cannot be either shortened or
lengthened. It is on this account that it is bent into the same curve
as the body of the insect. The mechanism by which this is effected is
similar to that of the tongue of the woodpeckers (_Picidae_), which,
though rather short, can be darted out far beyond the beak, by means of
a forked bone at the root of the tongue, which is thin and rolled up
like the spring of a watch. The base of the ovipositor of the gall-fly
is, in a similar way, placed near the anus, runs along the curvature of
the back, makes a turn at the breast, and then, following the curve of
the belly, appears again near where it originates. We copy from Reaumur
his accurate sketch of this remarkable structure.

With this instrument the mother gall-fly pierces the part of a plant
which she selects, and, according to our older naturalists, "ejects
into the cavity a drop of her corroding liquor, and immediately
lays an egg or more there; the circulation of the sap being thus
interrupted, and thrown, by the poison, into a fermentation that burns
the contiguous parts and changes the natural colour. The sap, turned
from its proper channel, extravasates and flows round the eggs, while
its surface is dried by the external air, and hardens into a vaulted
form."[GA] Kirby and Spence tell us, that the parent fly introduces
her egg "into a puncture made by her curious spiral sting, and in a
few hours it becomes surrounded with a fleshy chamber."[GB] M. Virey
says, the gall tubercle is produced by irritation, in the same way as
an inflamed tumor in an animal body, by the swelling of the cellular
tissue and the flow of liquid matter, which changes the organization,
and alters the natural external form.[GC] This seems to be the received
doctrine at present in France.[GD]

Sprengel, speaking of the rose-willow, says, the insect in spring
deposits its eggs in the leaf buds. "The new stimulus attracts the
sap,--the type of the part becomes changed, and from the prevailing
acidity of the animal juice, it happens, that in the rose and
stock-shaped leaves which are pushed out, a red instead of a green
colour is evolved."[GE]

[Illustration: Bedeguar Gall of the Rose, produced by _Cynips rosae_.]

Without pretending positively to state facts which are, perhaps, beyond
human penetration, we may view the process in a rather different
light. (J. R.) Following the analogy of what is _known_ to occur in
the case of the saw-flies, after the gall-fly has made a puncture
and pushed her egg into the hole, we may suppose that she covers it
over with some adhesive gluten or gum, or the egg itself, as is usual
among moths, &c., may be coated over with such a gluten. In either of
these two cases, the gluten will prevent the sap that flows through
the puncture from being scattered over the leaf and wasted; and the
sap, being thus confined to the space occupied by the eggs, will
expand and force outwards the pellicle of gluten that confines it,
till becoming thickened by evaporation and exposure to the air, it at
length shuts up the puncture, stops the further escape of the sap, and
the process is completed. This explanation will completely account for
the globular form of the galls alluded to; that is, supposing the egg
of the gall-fly to be globular, and covered or coated with a pellicle
of gluten of uniform thickness, and consequently opposing uniform
resistance, or rather uniform expansibility, to the sap pressing from
within. It will also account for the remarkable uniformity in the size
of the gall apples; for the punctures and the eggs being uniform in
size, and the gluten, by supposition, uniform in quantity, no more than
the same quantity of sap can escape in such circumstances.

But though this explanation appears to be plausible, it is confessedly
conjectural; for though Swammerdam detected a gall-fly in the act of
depositing her eggs, he did not attend to this circumstance; and in
the instances which we have observed, some unlucky accident always
prevented us from following up our observations. The indefatigable
Reaumur, on one occasion, thought he would make sure of tracing the
steps of the process in the case of the gall-fly which produces the
substance called _bedeguar_ on the wild rose-tree, and to which we
shall presently advert. His plan was to enclose in a box, in which a
brood of flies had just been produced from a bedeguar, a living branch
from a wild rose-tree; but, to his great disappointment, no eggs were
laid, and no bedeguar formed. Upon further investigation, he discovered
that the brood of flies produced from the bedeguar were not the genuine
bedeguar insects at all, but one of the parasite ichneumons (_Callimone
bedeguaris_, Stephens), which had surreptitiously deposited their eggs
there, in order to supply their young with the bedeguar grubs, all of
which they appeared to have devoured. It may prove interesting to look
into the remarkable structure of the bedeguar itself, which is very
different from the globular galls above described.

[Illustration: One of the bristles of the Bedeguar of the Rose
magnified.]

The gall-fly of the willow (_Cynips viminalis_) deposits, as we have
just seen, only a single egg on one spot; but the bedeguar insect lays
a large cluster of eggs on the extremity of a growing branch of the
wild rose-tree, making, probably, a proportionate number of punctures
to procure materials for the future habitation of her young progeny.
As in the former case, also, each of these eggs becomes (as we may
suppose) surrounded with the sap of the rose, enclosed in a pellicle of
gluten. The gluten, however, of the bedeguar insect is not, it would
appear, sufficiently tenacious to confine the flowing sap within the
dimensions of any of the little clustered globes containing the eggs,
for it oozes out from numerous cracks or pores in the pellicle; which
cracks or pores, however, are not large enough to admit a human hair.
But this, so far from being a defect in the glutinous pellicle of the
bedeguar fly, is, as we shall presently see, of great utility. The sap
which issues from each of these pores, instead of being evaporated and
lost, shoots out into a reddish-, fibrous bristle.

It is about half an inch long, and, from the natural tendency of the
sap of the rose-tree to form prickles, these are all over studded with
weak pricklets. The bedeguar, accordingly, when fully formed, has some
resemblance, at a little distance, to a tuft of reddish-brown hair
or moss stuck upon the branch. Sometimes this tuft is as large as a
small apple, and of a rounded but irregular shape; at other times it
is smaller, and in one instance mentioned by Reaumur, only a single
egg had been laid on a rose-leaf, and, consequently, only one tuft was
produced. Each member of the congeries is furnished with its own tuft
of bristles, arising from the little hollow globe in which the egg or
the grub is lodged.

The prospective wisdom of this curious structure is admirable. The
bedeguar grubs live in their cells through the winter, and as their
domicile is usually on one of the highest branches, it must be exposed
to every severity of the weather. But the close, non-conducting, warm,
mossy collection of bristles, with which it is surrounded, forms for
the soft, tender grubs a snug protection against the winter's cold,
till, through the influence of the warmth of the succeeding summer,
they undergo their final change into the winged state; preparatory
to which they eat their way with their sharp mandibles through the
walls of their little cells, which are now so hard as to be cut with
difficulty by a knife. (J. R.)

Another structure, similar in principle, though different in
appearance, is very common upon oak-trees, the termination of a branch
being selected as best suited for the purpose. This structure is rather
larger than a filbert, and is composed of concentric leaves diverging
from the base, and expanding upwards, somewhat like an artichoke.
Whether this leafy structure is caused by a superinduced disease,
as the French think, or by the form of the pores in the pellicle of
gluten surrounding the eggs, or rather by the tendency of the exuding
sap of the oak to form leaves, has not been ascertained; but that it
is intended, as in the case of the bedeguar, to afford an efficient
protection against the weather to the included eggs or grubs, there can
be no doubt.

[Illustration: Artichoke Gall of the Oak-bud, with Gall-fly (_Cynips
quercus gemmae_), natural size, and its ovipositor (_a_) magnified.]

From the very nature of the process of forming willow-galls, bedeguar,
and the artichoke of the oak, whatever theory be adopted, it will
be obvious that their growth must be rapid; for the thickening of
the exuded sap, which is quickly effected by evaporation, will soon
obstruct and finally close the orifice of the puncture made by the
parent insect. It is accordingly asserted by Reaumur and other
observers, that all the species of galls soon reach their full growth.

[Illustration: Leafy Gall of Dyer's Broom, produced by _Cynips
genistae_? A, gall, natural size; B, a leaflet magnified.]

A very minute reddish- grub feeds upon dyer's broom
(_Genista_), producing a sort of gall, frequently globular, but always
studded with bristles, arising from the amorphous leaves. The stem of
the shrub passes through this ball, which is composed of a great number
of leaves, shorter and broader than natural, and each rolled into the
form of a horn, the point of which ends in a bristle. In the interior
we find a thick fleshy substance, serving to sustain the leaves, and
also for the nourishment of the grubs, some of which are within and
some between the leaves. They are in prodigious numbers,--hundreds
being assembled in the small gall, and so minute as scarcely to be
perceived without the aid of a magnifying glass. The bud of the plant
attacked by those grubs, instead of forming a shoot, pushes out
nothing but leaves, and these are all rolled, and turned round the
stem. Some shrubs have several of these galls, which are of various
sizes, from that of a filbert to that of a walnut.

A similar but still more beautiful production is found upon one of the
commonest of our indigenous willows (_Salix purpurea_), which takes
the name of _rose-willow_, more probably from this circumstance than
from the red colour of its twigs. The older botanists, not being aware
of the cause of such excrescences, considered the plants so affected
as distinct species; and old Gerard accordingly figures and describes
the rose-willow as "not only making a gallant show, but also yielding
a most cooling air in the heat of summer, being set up in houses for
decking the same." The production in question, however, is nothing more
than the effect produced by a species of gall-fly (_Cynips salicis_)
depositing its eggs in the terminal shoot of a twig, and, like the
bedeguar and the oak artichoke, causing leaves to spring out, of a
shape totally different from the other leaves of the tree, and arranged
very much like the petals of a rose. Decandolle says it is found
chiefly on the _Salix helix_, _S. alba_, and _S. riparia_.[GF]

A production very like that of the rose-willow may be commonly met with
on the young shoots of the hawthorn, the growth of the shoot affected
being stopped, and a crowded bunch of leaves formed at the termination.
These leaves, besides being smaller than natural, are studded with
short bristly prickles, from the sap (we may suppose) of the hawthorn
being prevented from rising into a fresh shoot, and thrown out of
its usual course in the formation of the arms. These bristles appear
indiscriminately on both sides of the leaves, some of which are bent
inwards, while others diverge in their natural manner.

This is not caused by the egg or grub of a true gall-fly, but by the
small white tapering grub of some dipterous insect, of which we have
not ascertained the species, but which is, probably, a _cecidomyia_.
Each terminal shoot is inhabited by a number of these--not lodged in
cells, however, but burrowing indiscriminately among the half-withered
brown leaves which occupy the centre of the production. (J. R.)

A more remarkable species of gall than any of the above we discovered,
in June, 1829, on the twig of an oak in the grounds of Mr. Perkins,
at Lee, in Kent. When we first saw it, we imagined that the twig was
beset with some species of the lanigerous aphides, similar to what is
vulgarly called the American or white blight (_Aphis lanata_); but
on closer examination we discarded this notion. The twig was indeed
thickly beset with a white downy, or rather woolly, substance around
the stem at the origin of the leaves, which did not appear to be
affected in their growth, being well formed, healthy, and luxuriant. We
could not doubt that the woolly substance was caused by some insect;
but though we cut out a portion of it, we could not detect any egg
or grub, and we therefore threw the branch into a drawer, intending
to keep it as a specimen, whose history we might complete at some
subsequent period.

[Illustration: Semi-Gall of the Hawthorn, produced by _Cecidomyia_?
drawn from a specimen.]

A few weeks afterwards, on opening this drawer, we were surprised to
see a brood of several dozens of a species of gall-fly (_Cynips_),
similar in form and size to that whose eggs cause the bedeguar of the
rose, and differing only in being of a lighter colour, tending to
a yellowish brown. We have since met with a figure and description
of this gall in Swammerdam. We may remark that the above is not the
first instance which has occurred in our researches, of gall insects
outliving the withering of the branch or leaf from which they obtain
their nourishment.

[Illustration: Woolly Gall of the Oak, less than the natural size,
caused by a _Cynips_, and drawn from a specimen.]

The woolly substance on the branch of the oak which we have described
was similarly constituted with the bedeguar of the rose, with this
difference, that instead of the individual cells being diffused
irregularly through the mass, they were all arranged at the off-goings
of the leaf-stalks, each cell being surrounded with a covering of the
vegetable wool, which the stimulus of the parent egg, or its gluten,
had caused to grow, and from each cell a perfect fly had issued. We
also remarked that there were several small groups of individual cells,
each of which groups was contained in a species of calyx or cup of
leaf-scales, as occurs also in the well-known gall called the oak-apple.

We were anxious to watch the proceedings of these flies in the
deposition of their eggs, and the subsequent developments of the
gall-growths; and endeavoured for that purpose to procure a small oak
plant in a garden-pot; but we did not succeed in this: and though they
alighted on rose and sweet-briar trees, which we placed in their way,
we never observed that they deposited any eggs upon them. In a week or
two the whole brood died, or disappeared. (J. R.)

There are some galls, formed on low-growing plants, which are covered
with down, hair, or wool, though by no means so copiously as the one
which we have just described. Among the plants so affected are the
germander speedwell, wild thyme, ground-ivy, and others to which we
shall afterwards advert.

[Illustration: Oak-apple Galls, one being cut open to show the vessels
running to granules.]

The well-known oak-apple is a very pretty example of the galls formed
by insects; and this, when compared with other galls which form on the
oak, shows the remarkable difference produced on the same plant by the
punctures of insects of different species. The oak-apple is commonly
as large as a walnut or small apple, rounded, but not quite spherical,
the surface being irregularly depressed in various places. The skin is
smooth, and tinged with red and yellow, like a ripe apple; and at the
base there is, in the earlier part of the summer, a calyx or cup of
five or six small brown scaly leaves; but these fall off as the season
advances. If an oak-apple be cut transversely, there is brought into
view a number of oval granules, each containing a grub, and embedded
in a fruit-looking fleshy substance, having fibres running through
it. As these fibres, however, run in the direction of the stem, they
are best exhibited by a vertical section of the gall; and this also
shows the remarkable peculiarity of each fibre terminating in one of
the granules, like a footstalk, or rather like a vessel for carrying
nourishment. Reaumur, indeed, is of opinion that these fibres are the
diverted nervures of the leaves, which would have sprung from the bud
in which the gall-fly had inserted her eggs, and actually do carry
sap-vessels throughout the substance of the gall.

[Illustration: Root Galls of the Oak, produced by _Cynips quercus
inferus_? drawn from a specimen.]

Reaumur says the perfect insects (_Cynips quercus_) issued from his
galls in June and the beginning of July, and were of a reddish-amber
colour. We have procured insects, agreeing with Reaumur's description,
from galls formed on the bark or wood of the oak, at the line of
junction between the root and the stem. These galls are precisely
similar in structure to the oak-apple, and are probably formed at a
season when the fly perceives, instinctively, that the buds of the
young branches are unfit for the purpose of nidification.

There is another oak-gall, differing little in size and appearance from
the oak-apple, but which is very different in structure, as, instead
of giving protection and nourishment to a number of grubs, it is only
inhabited by one. This sort of gall, besides, is hard and woody on the
outside, resembling a little wooden ball of a yellowish colour, but
internally of a soft, spongy texture. The latter substance, however,
encloses a small hard gall, which is the immediate residence of the
included insect. Galls of this description are often found in clusters
of from two to seven, near the extremity of a branch, not incorporated,
however, but distinctly separate.

[Illustration: Woody Gall on a Willow branch, drawn from a specimen.]

We have obtained a fly very similar to this from a very common gall,
which is formed on the branches of the willow. Like the one-celled
galls just described, this is of a hard, ligneous structure, and forms
an irregular protuberance, sometimes at the extremity, and sometimes
on the body, of a branch. But instead of one, this has a considerable
number of cells, irregularly distributed through its substance. The
structure is somewhat spongy, but fibrous; and externally the bark is
smoother than that of the branch upon which it grows. (J. R.)

The currant-galls (as the French call them) of the oak are exactly
similar, when formed on the leaves, to those which we have first
described as produced on the leaves of the willow and other trees. But
the name of currant-gall seems still more appropriate to an excrescence
which grows on the catkins of the oak, giving them very much the
appearance of a straggling branch of currants or bird-cherries. The
galls resemble currants which have fallen from the tree before being
ripe. These galls do not seem to differ from those formed on the
leaves of the oak; and are probably the production of the same insect,
which selects the catkin in preference, by the same instinct that the
oak-apple gall-fly, as we have seen, sometimes deposits its eggs in the
bark of the oak near the root.

[Illustration: Currant Gall of the catkins of the Oak, produced by
_Cynips quercus pedunculi_?]

The gall of the oak, which forms an important dye-stuff, and is used
in making writing-ink, is also produced by a _Cynips_, and has been
described in the 'Library of Entertaining Knowledge' (Vegetable
Substances, p. 16). The employment of the _Cynips psenes_ for ripening
figs is described in the same volume, p. 244.

[Illustration: Gall of the Hawthorn Weevil, drawn from specimen. _a_,
Opened to show the grub.]


Gall of a Hawthorn Weevil.

In May, 1829, we found on a hawthorn at Lee, in Kent, the leaves at
the extremity of a branch neatly folded up in a bundle, but not quite
so closely as is usual in the case of leaf-rolling caterpillars. On
opening them, there was no caterpillar to be seen, the centre being
occupied with a roundish, brown-, woody substance, similar to
some excrescences made by gall-insects (_Cynips_). Had we been aware
of its real nature, we should have put it immediately under a glass or
in a box, till the contained insect had developed itself; but instead
of this, we opened the ball, where we found a small yellowish grub
coiled up, and feeding on the exuding juices of the tree. As we could
not replace the grub in its cell, part of the walls of which we had
unfortunately broken, we put it in a small pasteboard box with a fresh
shoot of hawthorn, expecting that it might construct a fresh cell.
This, however, it was probably incompetent to perform: it did not at
least make the attempt, and neither did it seem to feed on the fresh
branch, keeping in preference to the ruins of its former cell. To our
great surprise, although it was thus exposed to the air, and deprived
of a considerable portion of its nourishment, both from the part of
the cell having been broken off, and from the juices of the branch
having been dried up, the insect went through its regular changes, and
appeared in the form of a small greyish-brown beetle of the weevil
family. The most remarkable circumstance in the case in question, was
the apparent inability of the grub to construct a fresh cell after
the first was injured,--proving, we think, beyond a doubt, that it is
the puncture made by the parent insect when the egg is deposited that
causes the exudation and subsequent concretion of the juices forming
the gall. These galls were very abundant during the summer of 1830. (J.
R.)

A few other instances of beetles producing galls are recorded by
naturalists. Kirby and Spence have ascertained, for example, that the
bumps formed on the roots of kedlock or charlock (_Sinapis arvensis_)
are inhabited by the larvae of a weevil (_Curculio contractus_, Marsham;
and _Rhynchoenus assimilis_, Fabr.); and it may be reasonably supposed
that either the same or similar insects cause the clubbing of the
roots of cabbages, and the knob-like galls on turnips, called in some
places the _anbury_. We have found them also infesting the roots of
the hollyhock (_Alcea rosea_). They are evidently beetles of an allied
genus which form the woody galls sometimes met with on the leaves of
the guelder-rose (_Viburnum_), the lime-tree (_Tilia Europaea_), and the
beech (_Fagus sylvatica_).

There are also some two-winged flies which produce woody galls on
various plants, such as the thistle-fly (_Tephritis cardui_, Latr.).
The grubs of this pretty fly produce on the leaf-stalks of thistles
an oblong woody knob. On the common white briony (_Bryonia dioica_)
of our hedges may be found a very pretty fly of this genus, of a
yellowish-brown colour, with pellucid wings, waved much like those of
the thistle-fly with yellowish brown. This fly lays its eggs near a
joint of the stem, and the grubs live upon its substance. The joint
swells out into an oval form, furrowed in several places, and the
fly is subsequently disclosed. In its perfect state, it feeds on
the blossom of the briony. (J. R.) Flies of another minute family,
the gall-gnats (_Cecidomyiae_, Latr.), pass the first stage of their
existence in the small globular cottony galls which abound on germander
speedwell (_Veronica chamaedrys_), wild thyme (_Thymus serpyllum_), and
ground-ivy (_Glechoma hederacea_). The latter is by no means uncommon,
and may be readily recognised.

Certain species of plant-lice (_Aphides_), whose complete history would
require a volume, produce excrescences upon plants which may with some
propriety be termed galls, or semi-galls. Some of these are without
any aperture, whilst others are in form of an inflated vesicle, with
a narrow opening on the under side of a leaf, and expanding (for the
most part irregularly) into a rounded knob on its upper surface. The
mountain-ash (_Pyrus aucuparia_) has its leaves and young shoots
frequently affected in this way, and sometimes exhibits galls larger
than a walnut or even than a man's fist; at other times they do not
grow larger than a filbert. Upon opening one of these, they are found
to be filled with the _aphides sorbi_. If taken at an early stage of
their growth, they are found open on the under side of the leaf, and
inhabited only by a single female aphis, pregnant with a numerous
family of young. In a short time the aperture becomes closed, in
consequence of the insect making repeated punctures round its edge,
from which sap is exuded and forms an additional portion of the walls
of the cell.

[Illustration: A Plant-Louse (_Aphis_), magnified.]

In this early stage of its growth, however, the gall does not, like
the galls of the cynips, increase very much in dimensions. It is after
the increase of the inhabitants by the young brood that it grows with
considerable rapidity; for each additional insect, in order to procure
food, has to puncture the wall of the chamber and suck the juices, and
from the punctures thus made the sap exudes, and enlarges the walls.
As those galls are closed all round in the more advanced state, it
does not appear how the insects can ever effect an exit from their
imprisonment.

[Illustration: Galls produced on the leaves and leaf-stalks of the
Poplar by _Eriosoma populi_, with the various forms of the insects,
winged, not winged, and covered with wool, both of the natural size and
magnified.]

A much more common production, allied to the one just described, may
be found on the poplar in June and July. Most of our readers may have
observed, about midsummer, a small snow-white tuft of downy-looking
substance floating about on the wind, as if animated. Those tufts
of snow-white down are never seen in numbers at the same time, but
generally single, though some dozens of them may be observed in the
course of one day. This singular object is a four-winged fly (_Eriosoma
populi_, Leach), whose body is thickly covered with long down--a
covering which seems to impede its flight, and make it appear more
like an inanimate substance floating about on the wind, than impelled
by the volition of a living animal. This pretty fly feeds upon the
fresh juices of the black poplar, preferring that of the leaves and
leaf-stalks, which it punctures for this purpose with its beak. It
fixes itself with this design to a suitable place upon the principal
nervure of the leaf, or upon the leaf-stalk, and remains in the same
spot till the sap, exuding through the punctures, and thickening by
contact with the air, surrounds it with a thick fleshy wall of living
vegetable substance, intermediate in texture between the wood and the
leaf, being softer than the former and harder than the latter. In this
snug little chamber, secure from the intrusion of lady-birds and the
grubs of aphidivorous flies (_Syrphi_), she brings forth her numerous
brood of young ones, who immediately assist in enlarging the extent
of their dwelling, by puncturing the walls. In one respect, however,
the galls thus formed differ from those of the mountain-ash just
described,--those of the poplar having always an opening left into some
part of the cell, and usually in that portion of it which is elongated
into an obtuse beak. From this opening the young, when arrived at
the winged state, make their exit, to form new colonies; and, during
their migrations, attract the attention of the most incurious by the
singularity of their appearance. (J. R.)

On the black poplar there may be found, later in the season than the
preceding, a gall of a very different form, though, like the other, it
is for the most part on the leaf-stalk. The latter sort of galls are
of a spiral form; and though they are closed, they open upon slight
pressure, and appear to be formed of two laminae, twisted so as to
unite. It is at this opening that an aperture is formed spontaneously
for the exit of the insects, when arrived at a perfect state. In galls
of this kind we find aphides, but of a different species from the
lanigerous ones, which form the horn-shaped galls above described.


Leaf-Rolling Aphides.

It may not be improper to introduce here a brief sketch of some other
effects, of a somewhat similar kind, produced on leaves by other
species of the same family (_Aphidae_). In all the instances of this
kind which we have examined, the form which the leaf takes serves as a
protection to the insects, both from the weather and from depredators.
That there is design in it appears from the circumstance of the aphides
crowding into the embowering vault which they have formed; and we are
not quite certain whether they do not puncture certain parts of the
leaf for the very purpose of making it arch over them; at least, in
many cases, such as that of the hop-fly (_Aphis humuli_), though the
insects are in countless numbers, no arching of the leaves follows.
The rose-plant louse, again (_Aphis rosae_), sometimes arches the
leaves, but more frequently gets under the protecting folds of the
half-expanded leaf-buds. (J. R.)

[Illustration: Leaf of the Currant-bush, bulged out by the _Aphis
ribis_.]

One of the most common instances of what we mean occurs on the leaves
of the currant-bush, which may often be observed raised up into
irregular bulgings, of a reddish-brown colour. On examining the under
side of such a leaf there will be seen a crowd of small insects, some
with and some without wings, which are the _Aphides ribis_ in their
different stages, feeding securely and socially on the juices of the
leaf.

The most remarkable instance of this, however, which we have seen,
occurs on the leaves of the elm, and is caused by the _Aphis ulmi_.
The edge of an elm-leaf inhabited by those aphides is rolled up in an
elegant convoluted form, very much like a spiral shell; and in the
embowered chamber thus formed the insects are secure from rain, wind,
and partially from the depredations of carnivorous insects. One of
their greatest enemies, the lady-bird (_Coccinella_), seldom ventures,
as we have remarked, into concealed corners except in cold weather,
and contrives to find food enough among the aphides which feed openly
and unprotected, such as the zebra aphides of the alder (_Aphides
sambuci_). The grubs, however, of the lady-bird, and also those of the
aphidivorous flies (_Syrphi_), may be found prying into the most secret
recesses of a leaf to prey upon the inhabitants, whose slow movements
disqualify them from effecting an escape. (J. R.)

The effect of the puncture of aphides on growing plants is strikingly
illustrated in the shoots of the lime-tree and several other plants,
which become bent and contorted on the side attacked by the insects, in
the same way that a shoot might warp by the loss of its juices on the
side exposed to a brisk fire. The curvings thus effected become very
advantageous to the insects, for the leaves sprouting from the twig,
which naturally grow at a distance from each other, are brought close
together in a bunch, forming a kind of nosegay, that conceals all the
colour of the sprig, as well as the insects which are embowered under
it, protecting them against the rain and the sun, and at the same time
hiding them from observation. It is only requisite, however, where
they have formed bowers of this description, to raise the leaves, in
order to see the little colony of the aphides,--or the remains of those
habitations which they have abandoned. We have sometimes observed
sprigs of the lime-tree, of a thumb's thickness, portions of which
resembled spiral screws; but we could not certainly have assigned the
true cause for this twisting, had we not been acquainted with the
manner in which aphides contort the young shoots of this tree.[GG] The
shoots of the gooseberry and the willow are sometimes contorted in the
same way, but not so strikingly as the shoots of the lime.

[Illustration: Shoot of the Lime-tree contorted by the punctures of the
_Aphis tiliae_.]


Pseudo-Galls.

It may not be out of place to mention here certain anomalous
excrescences upon trees and other plants, which, though they much
resemble galls, are not so distinctly traceable to the operations of
any insect. In our researches after galls, we have not unfrequently
met with excrescences which so very much resemble them, that before
dissection we should not hesitate to consider them as such, and
predict that they formed the nidus of some species of insects. In more
instances than one we have felt so strongly assured of this, that we
have kept several specimens for some months, in nurse-boxes, expecting
that in due time the perfect insect would be disclosed.

One of these pseudo-galls occurs on the common bramble (_Rubus
fruticosus_), and bears some resemblance to the bedeguar of the rose
when old and changed by weather. It clusters round the branches in the
form of irregular granules, about the size of a pea, very much crowded,
the whole excrescence being rather larger than a walnut. We expected
to find this excrescence full of grubs, and were much surprised to
discover, upon dissection, that it was only a diseased growth of the
plant, caused (it might be) by the puncture of an insect, but not for
the purpose of a nidus or habitation. (J. R.)

[Illustration: Pseudo-gall of the Bramble, drawn from a specimen.]

Another sort of excrescence is not uncommon on the terminal shoots
of the hawthorn. This is in general irregularly oblong, and the bark
which covers it is of an iron colour, similar to the scoriae of a
blacksmith's forge. When dissected, we find no traces of insects, but
a hard, ligneous, and rather porous texture. It is not improbable that
this excrescence may originate in the natural growth of a shoot being
checked by the punctures of aphides, or of those grubs which we have
described.

Many of these excrescences, however, are probably altogether
unconnected with insects, and are simply hypertrophic diseases,
produced by too much nourishment, like the wens produced on animals.
Instances of this may be seen at the roots of the hollyhock (_Althea
rosea_) of three or four years' standing; on the stems of the elm and
other trees, immediately above the root; and on the upper branches of
the birch, where a crowded cluster of twigs sometimes grows, bearing
no distant resemblance to a rook's nest in miniature, and provincially
called witch-knots.

[Illustration: Pseudo-galls of the Hawthorn, drawn from specimens.]

One of the prettiest of these pseudo-galls with which we are
acquainted, is produced on the Scotch fir (_Pinus sylvestris_),
by the _Aphis pini_, which is one of the largest species of our
indigenous aphides. The production we allude to may be found, during
the summer months, on the terminal shoots of this tree, in the form
of a small cone, much like the fruit of the tree in miniature, but
with this difference, that the fruit terminates in a point, whereas
the pseudo-gall is nearly globular. Its colour also, instead of being
green, is reddish; but it exhibits the tiled scales of the fruit cone.

We have mentioned this the more willingly that it seems to confirm the
theory which we have hazarded respecting the formation of the bedeguar
of the rose and other true galls--by which we ascribed to the sap,
diverted from its natural course by insects, a tendency to form leaves,
&c., like those of the plant from which it is made to exude.

[Illustration: Pseudo-gall produced by _Aphis_ _pini_ on the Scotch
fir, drawn from a specimen.]




_CHAPTER XX._

ANIMAL GALLS,[GH] PRODUCED BY BREEZE-FLIES AND SNAIL-BEETLES.


The structures which we have hitherto noticed have all been formed of
inanimate materials, or at the most of growing vegetables; but those
to which we shall now advert are actually composed of the flesh of
living animals, and seem to be somewhat akin to the galls already
described as formed upon the shoots and leaves of plants. These were
first investigated by the accurate Vallisnieri, and subsequently by
Reaumur, De Geer, and Linnaeus; but the best account which has hitherto
been given of them is by our countryman Mr. Bracey Clark, who differs
essentially from his predecessors as to the mode in which the eggs are
deposited. As, in consequence of the extreme difficulty, if not the
impossibility, of personal observation, it is no easy matter to decide
between the conflicting opinions, we shall give such of the statements
as appear most plausible.

The mother breeze-fly (_Oestrus bovis_, Clark;--_Hypoderma bovis_,
Latr.), which produces the tumours in cattle called _wurbles_ or
_wormuls_ (_quasi_, _worm-holes_), is a two-winged insect, smaller,
but similar in appearance and colour to the carder-bee (p. 75), with
two black bands, one crossing the shoulders and the other the abdomen,
the rest being covered with yellow hair. This fly appears to have
been first discovered by Vallisnieri, who has given a curious and
interesting history of his observations upon its economy. "After having
read this account," says Reaumur, "with sincere pleasure, I became
exceedingly desirous of seeing with my own eyes what the Italian
naturalist had reported in so erudite and pleasing a manner. I did
not then imagine that it would ever be my lot to speak upon a subject
which had been treated with so much care and elegance; but since I have
enjoyed more favourable opportunities than M. Vallisnieri, it was not
difficult for me to investigate some of the circumstances better, and
to consider them under a different point of view. It is not, indeed,
very wonderful to discover something new in an object, though it has
been already carefully inspected with very good eyes, when we sit
down to examine it more narrowly, and in a more favourable position;
while it sometimes happens, also, that most indifferent observers
have detected what had been previously unnoticed by the most skilful
interpreters of nature."[GI]

From the observations made by Reaumur, he concluded that the
mother-fly, above described, deposits her eggs in the flesh of the
larger animals, for which purpose she is furnished with an ovipositor
of singular mechanism. We have seen that the ovipositors in the
gall-flies (_Cynips_) are rolled up within the body of the insect
somewhat like the spring of a watch, so that they can be thrust out to
more than double their apparent length. To effect the same purpose,
the ovipositor of the ox-fly lengthens, by a series of sliding tubes,
precisely like an opera-glass. There are four of these tubes, as may be
seen by pressing the belly of the fly till they come into view. Like
other ovipositors of this sort, they are composed of a horny substance;
but the terminal piece is very different indeed from the same part in
the gall-flies, the tree-hoppers (_Cicadae_), and the ichneumons, being
composed of five points, three of which are longer than the other
two, and at first sight not unlike a _fleur-de-lis_, though, upon
narrower inspection, they may be discovered to terminate in curved
points, somewhat like the claw of a cat. The two shorter pieces are
also pointed, but not curved; and by the union of the five, a tube is
composed for the passage of the eggs.

It would be necessary, Reaumur confesses, to see the fly employ this
instrument to understand in what manner it acts, though he is disposed
to consider it fit for boring through the hides of cattle. "Whenever I
have succeeded," he adds, "in seeing these insects at work, they have
usually shown that they proceeded quite differently from what I had
imagined; but unfortunately I have never been able to see one of them
pierce the hide of a cow under my eyes."[GJ]

[Illustration: Ovipositor of the Breeze-fly, greatly magnified, with a
claw and part of the tube, distinct.]

Mr. Bracey Clark, taking another view of the matter, is decidedly
of opinion that the fly does not pierce the skin of cattle with its
ovipositor at all, but merely glues its eggs to the hairs, while the
grubs, when hatched, eat their way under the skin. If this be the
fact, as is not improbable, the three curved pieces of the ovipositor,
instead of acting, as Reaumur imagined, like a centre-bit, will only
serve to prevent the eggs from falling till they are firmly glued to
the hair, the opening formed by the two shorter points permitting
this to be effected. This account of the matter is rendered more
plausible, from Reaumur's statement that the deposition of the egg
is not attended by much pain, unless, as he adds, some very sensible
nervous fibres have been wounded. According to this view, we must not
estimate the pain produced by the thickness of the instrument; for the
sting of a wasp, or a bee, although very considerably smaller than the
ovipositor of the ox-fly, causes a very pungent pain. It is, in the
latter case, the poison infused by the sting, rather than the wound,
which occasions the pain; and Vallisnieri is of opinion that the ox-fly
emits some acrid matter along with her eggs, but there is no proof of
this beyond conjecture.

It ought to be remarked, however, that cattle have very thick hides,
which are so far from being acutely sensitive of pain, that in
countries where they are put to draw ploughs and waggons, they find
a whip ineffectual to drive them, and have to use a goad, in form of
an iron needle, at the end of a stick. Were the pain inflicted by the
fly very acute, it would find it next to impossible to lay thirty or
forty eggs without being killed by the strokes of the ox's tail; for
though Vallisnieri supposes that the fly is shrewd enough to choose
such places as the tail cannot reach, Reaumur saw a cow repeatedly flap
its tail upon a part full of the gall-bumps; and in another instance he
saw a heifer beat away a party of common flies from a part where there
were seven or eight gall-bumps. He concludes, therefore, with much
plausibility, that these two beasts would have treated the ox-flies in
the same way, if they had given them pain when depositing their eggs.

The extraordinary effects produced upon cattle, on the appearance of
one of these flies, would certainly lead us to conclude that the pain
inflicted is excruciating. Most of our readers may recollect to have
seen, in the summer months, a whole herd of cattle start off across
a field in full gallop, as if they were racing,--their movements
indescribably awkward--their tails being poked out behind them as
straight and stiff as a post, and their necks stretched to their utmost
length. All this consternation has been known, from the earliest times,
to be produced by the fly we are describing. Virgil gives a correct
and lively picture of it in his Georgies,[GK] of which the following is
a translation, a little varied from Trapp:

    Round Mount Alburnus, green with shady oaks,
    And in the groves of Silarus, there flies
    An insect pest (named _Oestrus_ by the Greeks,
    By us _Asilus_): fierce with jarring hum
    It drives, pursuing, the affrighted herd
    From glade to glade; the air, the woods, the banks
    Of the dried river echo their loud bellowing.

Had we not other instances to adduce, of similar terror caused among
sheep, deer, and horses, by insects of the same genus, which are
ascertained not to penetrate the skin, we should not have hesitated to
conclude that Vallisnieri and Reaumur are right, and Mr. Bracey Clark
wrong. In the strictly similar instance of Reindeer-fly (_Oestrus
tarandi_, Linn.), we have the high authority of Linnaeus for the fact,
that it lays its eggs _upon_ the skin.

"I remarked," he says, "with astonishment how greatly the reindeer
are incommoded in hot weather, insomuch that they cannot stand still
a minute, no not a moment, without changing their posture, starting,
puffing and blowing continually, and all on account of a little fly.
Even though amongst a herd of perhaps five hundred reindeer, there were
not above ten of those flies, every one of the herd trembled and kept
pushing its neighbour about. The fly, meanwhile, was trying every means
to get at them; but it no sooner touched any part of their bodies, than
they made an immediate effort to shake it off. I caught one of these
insects as it was flying along with its tail protruded, which had at
its extremity a small linear orifice perfectly white. The tail itself
consisted of four or five tubular joints, slipping into each other
like a pocket spying-glass, which this fly, like others, has a power of
contracting at pleasure."[GL]

In another work he is still more explicit. "This well-known fly," he
says, "hovers the whole day over the back of the reindeer, with its
tail protruded and a little bent, upon the point of which it holds a
small white egg, scarcely so large as a mustard-seed, and when it has
placed itself in a perpendicular position, it drops its egg, which
rolls down amongst the hair to the skin, where it is hatched by the
natural heat and perspiration of the reindeer, and the grub eats its
way slowly under the skin, causing a bump as large as an acorn."[GM]
The male and female of the reindeer breeze-fly are figured in the
'Library of Entertaining Knowledge, Menageries,' vol. i. p. 405.

There is one circumstance which, though it appears to us to be of
some importance in the question, has been either overlooked or
misrepresented in books. "While the female fly," say Kirby and Spence,
"is performing the operation of oviposition, the animal attempts to
lash her off as it does other flies, with its tail;"[GN] though this
is not only at variance with their own words in the page but one
preceding, where they most accurately describe "the herd with their
tails in the air, or turned upon their backs, or stiffly stretched out
in the direction of the spine,"[GO] but with the two facts mentioned
above from Reaumur, as well as with common observation. If the ox
then do not attempt to lash off the breeze-fly, but runs with its
tail stiffly extended, it affords a strong presumption that the fly
terrifies him by her buzzing (_asper_, _acerba sonans_), rather than
pains him by piercing his hide: her buzz, like the rattle of the
rattlesnake, being instinctively understood, and intended, it may be,
to prevent an over-population, by rendering it difficult to deposit the
eggs.

The horse breeze-fly (_Gasterophilus equi_, Leach), which produces the
maggots well known by the name of _botts_ in horses, is ascertained
beyond a doubt to deposit her eggs upon the hair; and as insects of the
same genus almost invariably proceed upon similar principles, however
much they may vary in minute particulars, it may be inferred with
justice, that the breeze-flies which produce galls do the same. The
description given by Mr. Bracey Clark, of the proceedings of the horse
breeze-fly, is exceedingly interesting.

"When the female has been impregnated, and her eggs sufficiently
matured, she seeks among the horses a subject for her purpose, and
approaching him on the wing, she carries her body nearly upright in the
air, and her tail, which is _lengthened for the purpose_,[GP] curved
inwards and upwards; in this way she approaches the part where she
designs to deposit the egg; and suspending herself for a few seconds
before it, suddenly darts upon it and leaves the egg adhering to the
hair; she hardly appears to settle, but merely touches the hair with
the egg _held out on the projected point of the abdomen_.[GP] The egg
is made to adhere by means of a glutinous liquor secreted with it. She
then leaves the horse at a small distance, and prepares a second egg,
and poising herself before the part, deposits it in the same way. The
liquor dries, and the egg becomes firmly glued to the hair: this is
repeated by these flies till four or five hundred eggs are sometimes
placed on one horse."

Mr. Clark farther tells us, that the fly is careful to select a part
of the skin which the horse can easily reach with his tongue, such as
the inside of the knee, or the side and back part of the shoulder.
It was at first conjectured, that the horse licks off the eggs thus
deposited, and that they are by this means conveyed into its stomach;
but Mr. Clark says, "I do not find this to be the case, or at least
only by accident; for when they have remained on the hair four or five
days, they become ripe, after which time the slightest application of
warmth and moisture is sufficient to bring forth, in an instant, the
latent larva. At this time, if the tongue of the horse touches the egg,
its operculum is thrown open, and a small, active worm is produced,
which readily adheres to the moist surface of the tongue, and is thence
conveyed with the food to the stomach." He adds, that "a horse which
has no ova deposited on him may yet have botts, by performing the
friendly office of licking another horse that has."[GQ] The irritations
produced by common flies (_Anthomyiae meteoricae_, Meigen) are alleged as
the incitement to licking.

The circumstance, however, of most importance to our purpose, is the
agitation and terror produced both by this fly and by another horse
breeze-fly (_Gasterophilus haemorrhoidalis_, Leach), which deposits
its eggs upon the lips of the horse as the sheep breeze-fly (_Oestrus
ovis_) does on that of the sheep. The first of these is described
by Mr. Clark as "very distressing to the animal, from the excessive
titillation it occasions; for he immediately after rubs his mouth
against the ground, his fore-feet, or sometimes against a tree, with
great emotion; till, finding this mode of defence insufficient, he
quits the spot in a rage, and endeavours to avoid it by galloping
away to a distant part of the field, and if the fly still continues
to follow and teaze him, his last resource is in the water, where the
insect is never observed to pursue him. These flies appear sometimes
to hide themselves in the grass, and as the horse stoops to graze
they dart upon the mouth or lips, and are always observed to poise
themselves during a few seconds in the air, while the egg is prepared
_on the extended point of the abdomen_."[GR]

The moment the second fly just mentioned touches the nose of a sheep,
the animal shakes its head and strikes the ground violently with its
fore-feet, and at the same time holding its nose to the earth, it runs
away, looking about on every side to see if the flies pursue. A sheep
will also smell the grass as it goes, lest a fly should be lying in
wait, and if one be detected, it runs off in terror. As it will not,
like a horse or an ox, take refuge in the water, it has recourse to
a rut or dry dusty road, holding its nose close to the ground, thus
rendering it difficult for the fly to get at the nostril.

[Illustration: _a_, The belly of the grub. _b_, Its back. _c_, The tail
of the grub, greatly magnified. _d_, The bump, or gall, having its
external aperture filled with the tail of the grub.]

When the egg of the ox breeze-fly (_Hypoderma bovis_, Latr.) is
hatched, it immediately (if Mr. Bracey Clark be correct) burrows into
the skin; while, according to Reaumur, it is hatched there. At all
events, the grub is found in a bump on the animal's back, resembling
a gall on a tree,--"a place," says Reaumur, "where food is found in
abundance, where it is protected from the weather, where it enjoys
at all times an equal degree of warmth, and where it finally attains
maturity."[GS] When in an advanced stage, the bumps appear much like
the swellings produced upon the forehead by a smart blow. These, with
the grubs, are represented in the foregoing figure, and also at page
434.

Every bump, according to Reaumur, has in its inside a cavity, which is
a lodging proportionate to the size of the insect. The bump and cavity
also increase in proportion to the growth of the grub. It is not until
about the middle of May that these bumps can be seen full grown. Owing
to particular circumstances, they do not all attain an equal size. The
largest of them are sixteen or seventeen lines in diameter at their
base, and about an inch high; but they are scarcely perceptible before
the beginning or during the course of the winter.

[Illustration: Fly, maggot, and grub of the Ox breeze-fly, with a
microscopic view of the maggot.]

It is commonly upon young cattle, such, namely, as are two or three
years old, that the greatest number of bumps is found; it being rare
to observe them upon very old animals. The fly seems to be well aware
that such skins will not oppose too much resistance, and seems to
know, also, that tender flesh is the most proper for supplying good
nourishment to its progeny. "And why," asks Reaumur, "should not the
instinct which conducts it to confide its eggs to the flesh of certain
species only, lead it to prefer the flesh of animals of the same
species which is most preferable?" The number of bumps which are found
upon a beast is equal to the number of eggs which have been deposited
in its flesh; or, to speak more correctly, to the number of eggs which
have succeeded, for apparently all are not fertile; but this number
is very different upon different cattle. Upon one cow only three or
four bumps may be observed, while upon another there will appear from
thirty to forty. They are not always placed on the same parts, nor
arranged in the same manner: commonly, they are near the spine, but
sometimes upon or near the thighs and shoulders. Sometimes they are at
remote distances from each other; at other times they are so near that
their circumferences meet. In certain places, three or four tumors may
be seen touching each other; and more than a dozen sometimes occur
arranged as closely together as possible.

It is very essential to the grub that the hole of the tumor should
remain constantly open; for by this aperture a communication with
the air necessary for respiration is preserved; and the grub is
thence placed in the most favourable position for receiving air. Its
spiracles for respiration, like those of many other grubs, are situated
immediately upon the posterior extremity of the body. Now, being almost
always placed in such a situation as to have this part above, or upon a
level with the external aperture, it is enabled to respire freely.[GT]

[Illustration: Bumps or wurbles produced on cattle by the Ox
breeze-fly.]

We have not so many examples of galls of this kind as we have of
vegetable galls; and when we described the surprising varieties of
the latter, we did not perceive that it was essential to the insects
inhabiting them to preserve a communication with the external air:
in the galls of trees, openings expressly designed or kept free for
the admission of air are never observed. Must the grub, then, which
inhabits the latter have less need of respiring air than the grub
of the breeze-flies in a flesh-gall? Without doubt, not; but the
apertures by which the air is admitted to the inhabitants of the
woody gall, although they may escape our notice, in consequence of
their minuteness, are not, in fact, less real. We know that, however
careful we may be in inserting a cork into a glass, the mercury with
which it is filled is not sheltered from the action of the air, which
weighs upon the cork; we know that the air passes through, and acts
upon the mercury in the tube. The air can also, in the same way,
penetrate through the obstruction of a gall of wood, though it have no
perceptible opening or crack; but the air cannot pass in this manner so
readily through the skins and membranes of animals.

In order to see the interior of the cavity of an animal gall,
Reaumur opened several, either with a razor or a pair of scissors;
the operation, however, cannot fail to be painful to the cow, and
consequently renders it impatient under the process. The grub being
confined in a tolerably large fistulous ulcer, a part of the cavity
must necessarily be filled with pus or matter. The bump is a sort of
cautery, which has been opened by the insect, as issues are made by
caustic: the grub occupies this issue, and prevents it from closing.
If the pus or matter which is in the cavity, and that which is daily
added to it, had no means of escaping, each tumor would become a
considerable abscess, in which the grub would perish; but the hole of
the bump, which admits the entrance of the air, permits the pus or
matter to escape; that pus frequently mats the hairs together which
are above the small holes, and this drying around the holes acquires a
consistency, and forms in the interior of the opening a kind of ring.
This matter appears to be the only aliment allowed for the grub, for
there is no appearance that it lives, like the grubs of flesh-flies,
upon putrescent meat. Mandibles, indeed, similar to those with which
other grubs break their food, are altogether wanting. A beast which
has thirty, forty, or more of these bumps upon its back, would be in a
condition of great pain and suffering, terrible indeed in the extreme,
if its flesh were torn and devoured by as many large grubs; but there
is every appearance that they do not at all afflict, or only afflict it
with little pain. For this reason cattle most covered with bumps are
not considered by the farmer as injured by the presence of the fly,
which generally selects those in the best condition.

A fly, evidently of the same family with the preceding, is described
in Bruce's 'Travels,' under the name of zimb, as burrowing during its
grub state in the hides of the elephant, the rhinoceros, the camel, and
cattle. "It resembles," he says, "the gad-fly in England, its motion
being more sudden and rapid than that of a bee. There is something
peculiar in the sound or buzzing of this insect; it is a jarring noise
together with a humming, which as soon as it is heard all the cattle
forsake their food and run wildly about the plain till they die, worn
out with fatigue, fright, and hunger. I have found," he adds, "some of
these tubercles upon almost every elephant and rhinoceros that I have
seen, and attribute them to this cause. When the camel is attacked
by this fly, his body, head, and legs break out into large bosses,
which swell, break, and putrefy, to the certain destruction of the
creature."[GU] That camels die under such symptoms, we do not doubt;
but we should not, without more minutely-accurate observation, trace
all this to the breeze-fly.

MM. Humboldt and Bonpland discovered, in South America, a species,
probably of the same genus, which attacks man himself. The perfect
insect is about the size of our common house-fly (_Musca domestica_),
and the bump formed by the grub, which is usually on the belly, is
similar to that caused by the ox breeze-fly. It requires six months to
come to maturity; and if it is irritated it eats deeper into the flesh,
sometimes causing fatal inflammations.


Grub Parasite in the Snail.

During the summer of 1829, we discovered in the hole of a garden-post,
at Blackheath, one of the larger grey snail shells (_Helix aspersa_,
Muller), with three white soft-bodied grubs burrowing in the body of
the snail. They evidently, from their appearance, belonged to some
species of beetle, and we carefully preserved them in order to watch
their economy. It appeared to us that they had attacked the snail
in its stronghold while it was laid up torpid for the winter; for
more than half of the body was already devoured. They constructed
for themselves little cells attached to the inside of the shell, and
composed of a sort of fibrous matter, having no distant resemblance
to shag tobacco, both in form and smell, and which could be nothing
else than the remains of the snail's body. Soon after we took them,
appearing to have devoured all that remained of the poor snail, we
furnished them with another, which they devoured in the same manner.
They formed a cocoon of the same fibrous materials during the autumn,
and in the end of October appeared in their perfect form, turning out
to be _Drilus flavescens_, the grub of which was first discovered in
France in 1824. The time of their appearance, it may be remarked,
coincides with the period when snails become torpid. (J. R.)

In the following autumn, we found a shell of the same species with a
small pupa-shaped egg deposited on the lid. From this a caterpillar was
hatched, which subsequently devoured the snail, spun a cocoon within
the shell, and was transformed into a small moth (of which we have not
ascertained the species) in the spring of 1830.

[Before concluding the account of the parasite insects, it will be
necessary to mention two of our British Ichneumonidae, which not
only deposit their eggs in the larvae of other insects, but make for
themselves cells of very beautiful structure. In the accompanying
illustration are shown the cells of one of our commonest and most
useful ichneumonidae (_Microgaster glomeratus_), together with the
insect itself. At Fig. 1_a_ (p. 438) is shown the little insect of the
natural size, and the same is given at 1 much magnified.

This creature lays its eggs in the body of the cabbage caterpillar,
forty or fifty eggs being deposited in the same larva. They soon hatch
into little transparent grubs, which lie under the skin, and live on
the fatty parts of the caterpillar, which continues to grow, and seems
to thrive, whereas its bulk is largely made up of the ichneumon larvae.

[Illustration: Microgaster glomeratus.]

After the caterpillar ceases from feeding, it crawls aside for the
purpose of assuming the pupal state. But, before it can do so, the
ichneumon larvae, which have also ceased from feeding, burst their way
through the sides of the caterpillar, and immediately begin to spin
their cocoon. These are oval, very small, and covered with yellow silk.
A group of these cocoons is shown at Fig. 3. The innumerable fibres
of these cocoons hamper the caterpillars so much that, in most cases,
it seldom is able to stir from the spot, but dies in the midst of its
enemies. Groups of these yellow cocoons can be found in every wall
or paling near cabbage gardens. In a few days, the larvae have passed
through their pupal stage, assuming the winged state, and emerge from
the cocoons through little circular doors, as seen in Fig. 2.

Our second illustration represents another species, _Microgaster
alveolarius_, together with its cocoons. As before, the insect is shown
of its natural size at la, and magnified at 1. The preliminary life of
this insect is exactly the same as that of the preceding; but, instead
of making a number of independent and separate cocoons, the insects
spin so closely together that they form an edifice very much resembling
a bee-comb. Fig. 5 represents one of these cell-groups of the natural
size, and the edge of another group is shown at Fig. 4. A longitudinal
section, slightly enlarged, is given at 3, in order to show the
hexagonal shape assumed by the aggregated cells; and Fig. 2 shows the
little lids which open to give egress to the insect. All these figures
are drawn from specimens in my collection.]

[Illustration: Microgaster alveolarius.]




THE END.


  LONDON: PRINTED BY W. CLOWES AND SONS, STAMFORD STREET AND
  CHARING CROSS.






FOOTNOTES:

[A] Stephens' Illustrations, vol. i., p. 72, note.

[B] Contemplation de la Nature, part ii. ch. 42.

[C] The original observations in this volume which are marked by the
initials J. R., are by J. Rennie, A.M., A.L.S., and those which are
enclosed in brackets are by the Rev. J. G. Wood, M.A., F.L.S.

[D] Introduction to Entomology, vol. i.

[E] Dunciad, book iv.

[F] Humboldt, Voyage, lib. vii., ch. 20.

[G] Amer. Ornith., i., p. 144.

[H] Amer. Ornith., iii., p. 21.

[I] Blumenbach; see also Insect Transformations, p. 231.

[J] Nomina si pereant, perit et cognitio rerum.

[K] J. R., in Mag. of Natural History, vol. i., p. 334.

[L] Miss Jermyn's Butterfly Collector, p. 11.

[M] Generally to ametabolous pupae.

[N] See Spallanzani's Tracts, by Dalyell, vol. i.

[O] Ray, Hist. Insect., 254.

[P] The fifth order of Linnaeus; insects with four transparent veined
wings.

[Q] Naturalist's Calendar, p. 100.

[R] Introduction to Entomology, vol. i. p. 435, 5th edit.

[S] See p. 50.

[T] Shapeless.

[U] The Owl observed by Vieillot in St. Domingo digs itself a burrow
two feet in depth, at the bottom of which it deposits its eggs upon a
bed of moss.

[V] American Ornithology, by Charles Lucien Bonaparte, vol. i. p. 69.

[W] Reaumur, vol. vi. bottom of page 182; Hist. of Selb. ii. 228; and
Introd. to Entomol. i. 504, 5th edition.

[X] In the Mag. of Nat. Hist. 1839, p. 458, Mr. Shuckard gives
an account of the nest of a wasp, which he regards as _Vespa
Britannica_,--remarkable for the material of which it was constructed,
and for the locality in which it was found. This nest, which was
exhibited at a meeting of the Entomological Society, was found near
Croydon, built in a sparrow's nest, and attached to the lining
feathers. "The smallness of the nest," says Mr. Shuckard, "and also
of the tier of cells, as well as the peculiar material of which it
appeared composed, led to a discussion, the tendency of which seemed to
support the opinion that it was most probably the nest of a _Polistes_,
a social-wasp not yet found in this country, but if not of _Polistes_,
certainly not yet determined or known." The nest was ovate, about an
inch and a half long, with a tier of cells internally, originating from
a common pedicle. It appeared to be constructed "of the agglutinated
particles of a soft white wood, probably willow, very imperfectly
triturated;" whence it had externally a rough granulated appearance. It
was sprinkled with black specks, arising perhaps from the intermixture
of more decayed portions of the wood; and was of a very fragile
texture. "The nature of the material, and its unfinished execution, as
well as the situation in which it was found, appear to me to be its own
peculiarities, and I must necessarily consider it merely an accidental
variation in material and locality from the usual nests of the _Vespa
Britannica_ of Leach."

[Y] Memoires sur les Insectes, tom. vi., mem. vii. See also Bonnet
vol. ix.

[Z] It is right to remark that Huish and others have suggested that
the grubs thus royalized may originally be misplaced queens; yet
this admission is not necessary, since Madlle. Jurine has proved, by
dissection, the workers to be imperfect females.

[AA] Huber on Bees, p. 338.

[AB] Melisselogia, or Female Monarchy, 8vo., Lond. 1744.

[AC] De la Pluche, Spectacle de la Nature, vol. i.

[AD] Philosophical Trans. for 1792, p. 143.

[AE] Huber on Bees.

[AF] American Quarterly Review for June, 1828, p. 382.

[AG] Latreille, Mem. Acad. des Sciences, 1821.

[AH] Huber on Bees, p. 325.

[AI] From two Greek words [Greek: pro polis] meaning _before the city_,
as the substance is principally applied to the projecting parts of the
hive.

[AJ] Phil. Trans. for 1807, p. 242.

[AK] Schirach, Hist. des Abeilles, p. 241.

[AL] Kirby and Spence observed bees very busy in collecting propolis
from the tacamahaca-tree (_Populus balsamifera_).--Introd., ii. 186.

[AM] Huber on Bees, p. 408.

[AN] Philosophical Trans. for 1807, p. 242.

[AO] Spectacle de la Nature, tome i.

[AP] Huber on Bees, p. 358.

[AQ] Reaumur, vol. v., p. 380.

[AR] Huber on Bees, p. 368.

[AS] Huber on Bees, p. 220.

[AT] Memoirs of the Wernerian Nat. Hist. Soc., vol. ii. p. 260.

[AU] Bevan on Bees, p. 326.

[AV] Huber on Bees, p. 416.

[AW] Huber on Bees, p. 391.

[AX] From two Greek words, signifying _pitch_ and _wax_.

[AY] Huber on Bees, p. 415.

[AZ] Spectacle de la Nature, vol. i.

[BA] North American Rev., Oct. 1828, p. 355.

[BB] "Hibernia dives lactis ac _mellis_ insula."--Beda, Hist.
Eccles. i. 7.

[BC] Deut. xxxii. 13.

[BD] Psalm lxxxi. 16.

[BE] Forbes, Orien. Mem. i.

[BF] Amer. Q. Rev., iii. p. 383.

[BG] Roy. Mil. Chron. quoted by Kirby and Spence.

[BH] "Cantu querulae rumpent arbusta cicadae."--Georg. iii. 328.

[BI] A line is about the twelfth part of an inch.

[BJ] Introd., vol. i. p. 457.

[BK] Roesel, cl. ii., Pap. Nocturn., tab. xx. fig. 1, 2, 3, 4, 5, 6.

[BL] See p. 100.

[BM] Contemplation de la Nature, part XV. chap. 38.

[BN] A cement prepared of volcanic earth, or lava.

[BO] It is justly remarked by Reaumur, that when caterpillars are left
at liberty among their native plants, it is only by lucky chance they
can be observed building their cocoons, because the greater number
abandon the plants upon which they have been feeding, to spin up in
places at some distance. In order to see their operations, they must
be kept in confinement, particularly in boxes with glazed doors,
where they may be always under the eye of the naturalist. In such
circumstances, however, we may be ignorant what building materials we
ought to provide them with for their structures. A red caterpillar,
with a few tufts of hair, which Reaumur found in July feeding upon
the flower bunches of the nettle, and refusing to touch the leaves,
began in a few days to prepare its cocoon, by gnawing the paper lid
of the box in which it was placed. This, of course, was a material
which it could not have procured in the fields, but it was the nearest
in properties that it could procure; for, though it had the leaves
and stems of nettles, it never used a single fragment of either. When
Reaumur found that it was likely to gnaw through the paper lid of the
box, and might effect its escape, he furnished it with bits of rumpled
paper, fixed to the lid by means of a pin; and these it chopped down
into such pieces as it judged convenient for its structure, which
it took a day to complete. The moth appeared four weeks after, of a
brownish-black colour, mottled with white, or rather grey, in the
manner of lace.

Bonnet also mentions more than one instance in which he observed
caterpillars making use of paper, when they could not procure other
materials.

[BP] Kirby, in 'Linn. Trans.,' vol. v. p. 246, and Introd. ii.

[BQ] See Fig. _d_, p. 238.

[BR] Reaumur, 'Mem. Hist. Insectes,' iii. 70.

[BS] 'Contemplation de la Nature,' part xii. chap. x. note.

[BT] 'Animal Biography,' vol. iii. p. 330, Third Edition.

[BU] Bonnet, xi. p. 204; Kirby and Spence, 'Introduction,' i. 464,
Fifth Edition.

[BV] Bonnet, vol. ix. p. 203.

[BW] 'Mem. Hist. Insect.' iii. p. 106.

[BX] Reaumur, iii. p. 130.

[BY] Bonnet, 'Contempl. de la Nature,' part xii.

[BZ] Swammerd., 'Book of Nature,' vol. ii. p. 84.

[CA] 'Contempl. de la Nature,' part xii. p. 197.

[CB] Bonnet, 'Observ. sur les Insectes,' vol. ii. p. 425.

[CC] Dict. Classique d'Hist. Nat. Art. Grillon.

[CD] Natural History of Selborne, ii. 82.

[CE] Entomologie, par R. A. E. 18mo., Paris, 1826, p. 168.

[CF] Natural History of Selborne.

[CG] Act. Acad. Berolin. 1752, et Gleditsch, Phys. Botan., quoted by
Kirby and Spence, ii. 353.

[CH] Moufet, 153. Kirby and Spence, ii. 350.

[CI] Journal of a Naturalist, p. 311.

[CJ] Bingley, Anim. Biog., vol. iii, p. 230.

[CK] Phil. Trans., vol. xliv. p. 579.

[CL] Anim. Biog., vol. iii. p. 233.

[CM] Anderson's Recr. in Agricult., vol. iii. p. 420.

[CN] Hints, p. 74.

[CO] Journal of a Naturalist, p. 304.

[CP] A line is the twelfth part of the old French inch. _See_ Companion
to the Almanac for 1830, p. 114.

[CQ] M. P. Huber on Ants, p. 20.

[CR] Stedman's Surinam, vol. i. p. 160.

[CS] M. P. Huber on Ants, p. 23.

[CT] Latreille, Hist. Nat. des Fourmis.

[CU] Dr. Cleghorn, Thesis de Somno.

[CV] Aristotle Hist. Animal. ix. 38. Pliny says, "Operantur et noctu
plena luna; eadem interlunio cessant," _i.e._, They work in the night
at full moon, but they leave off between moon and moon. It is the
latter that we think doubtful.

[CW] M. P. Huber on Ants, p. 31.

[CX] Huber on Ants, p. 43.

[CY] In formica non modo sensus, sed etiam mens, ratio, memoria.

[CZ] Aldrovandus de Formicis, and Johnston, Thaumaturg. Nat. p. 356.

[DA] See Professor Paxton's Illustrations of Scripture, i. 307.

[DB] Huber on Ants, p. 15.

[DC] Huber on Ants, p. 11.

[DD] Huber, p. 56.

[DE] The acid of ants.

[DF] Huber.

[DG] Hawkesworth's Account of Cook's First Voyage.

[DH] Phil. Trans., xxx. p. 346.

[DI] Jobson's Gambia, in Purchas's Pilgrim, ii. p. 1570.

[DJ] Heber's Journal, vol. i. p. 248.

[DK] Smeathman, in Phil. Trans., vol. lxxi.

[DL] Smeathman.

[DM] Quoted by De Geer, vol. vii.

[DN] Hist. Nat. Generale, vol. xiii. p. 66.

[DO] Smeathman, in Phil. Trans., vol. lxxi. p. 169, note.

[DP] Latreille, Hist. Nat. Generale, tom. xiii. p. 64.

[DQ] Lyonnet.

[DR] Spectacle de la Nature, vol. i.

[DS] Cours d'Agriculture, par M. Rozier. Paris, 1801.

[DT] This is denied by recent observers.

[DU] Spectacle de la Nature, vol. i.

[DV] Count Dandolo's Art of Rearing Silk-Worms, Eng. Transl., p. 215.

[DW] On a tort de croire que le bruit nuise a ces insectes, Hist. Nat.
Generale, vol. xiii. p. 170.

[DX] Shaw's Gen. Zoology, vol. vi.

[DY] North American Review, Oct. 1828, p. 449.

[DZ] Essay on the Silk-Worm, p. 95. London, 1719.

[EA] Preface to Dandolo on the Silk-Worm, Eng. Transl., p. xiii.

[EB] Glover's Directory of the County of Derby, Introd., p. xvi.

[EC] Memecken, quoted by Kirby and Spence, iii. 280.

[ED] Brahm's Ins. Nat. 289, and Kirby and Spence's Intr. iii, 223.

[EE] De Geer, Mem. i. 319.

[EF] Curtis, Hist. of Brown-tail Moth, 4to. London, 1782.

[EG] Reaumur, ii. p. 137.

[EH] Salisbury, Hints on Orchards, p. 53.

[EI] Hardy's Travels in the Interior of Mexico, p. 32.

[EJ] Hill's Swammerdam, part i. p. 23.

[EK] Swammerdam, part i. p. 24.

[EL] Intr., vol. i. p. 415.

[EM] Kirby and Spence, vol. i. Intr. p. 416.

[EN] Porcupines do not shoot out their quills, as was once generally
believed.

[EO] Lister, Hist. Animalia Angliae, 4to. p. 7.

[EP] Phil. Mag., ii. p. 275.

[EQ] Vol. i. Intr., p. 417.

[ER] Phil. Mag.,, ii. p. 339.

[ES] Nat. Hist. of Selborne, vol. i. p. 327.

[ET] Book of Nature, part i. p. 25.

[EU] Hist. Anim. Angliae, 4to.

[EV] Memoires, vol. vii. p. 189.

[EW] Spectacle de la Nature, vol. i.

[EX] Book of Nature, part i. p. 25.

[EY] Animal Biography, vol. iii. p. 475, 3rd edition.

[EZ] Brez, Flore des Insectophiles. Notes, Supp. p. 134.

[FA] Thomson's Ann. of Philosophy, vol. iii. p. 306.

[FB] Loudon's Mag. of Nat. Hist., vol. i. p. 322.

[FC] Experim. Researches in Nat. Hist., p. 136.

[FD] Mag. Nat. Hist., vol. i. p. 324.

[FE] Linn. Trans., vol. xv. p. 456.

[FF] Mag. Nat. Hist., vol. ii. p. 397.

[FG] Linn. Trans., vol. xv. p. 453.

[FH] "----L'un des bouts de ces premiers fils, afin que le vent ou
un courant d'air pousse l'autre extremite de l'un d'eux au de la de
l'obstacle."--Dict. Classique d'Hist. Nat., vol. i. p. 510.

[FI] Evelyn's Travels in Italy.

[FJ] Book of Nature, part i. p. 24.

[FK] Bloomfield's Remains, vol. ii. p. 64, _note_.

[FL] Animal Biography, iii. 470-1.

[FM] Mem. de l'Acad. des Sciences pour 1707, p. 339.

[FN] Kirby and Spence, Intr. i. 419.

[FO] Darwin's Zoonomia, i. 253, 8vo. ed.

[FP] Mem. Soc. d'Hist. Nat. de Paris, An. vii.

[FQ] Mem. Soc. d'Hist. Nat. de Paris, p. 125, and Latreille, Hist. Nat. Geuer. viii. p. 163.

[FR] Kirby and Spence, Intr. i. 425.

[FS] Aranei Suecici, Stockholm, 1757.

[FT] Mem. des Araign. Aquat., 12mo. Paris, 1799.

[FU] Clerck, Aranei Suecici, cap. viii.

[FV] De Geer, Mem. des Insectes, vii. 312.

[FW] Spectacle de la Nature, i. 58.

[FX] Linn. Trans. vol. xv.

[FY] Spectacle de la Nature, i. p. 61.

[FZ] Remains, ii. 62-5. It is a remarkable fact, as recorded from
personal observation by Mr. Bell (British Reptiles), that the toad
swallows the cuticle detached from its body during the moult which it
undergoes.

[GA] Spectacle de la Nature, i. 119.

[GB] Introduction, ii. 449.

[GC] Hist. des Moeurs et de l'Instinct, vol. ii.

[GD] Entomologie, par R. A. E., p. 242. Paris, 1826.

[GE] Elements of the Philosophy of Plants, Eng. Trans., p. 285.

[GF] Flore Franc. Disc. Preliminaire.

[GG] Reaumur, vol. iii.

[GH] In order to prevent ambiguity, it is necessary to remark that the
excrescences thus called must not be confounded with the true galls,
which are occasionally found in the gall-bladder.

[GI] Reaumur, Mem. iv. 505.

[GJ] Mem. iv. 538.

[GK]

    Est lucos Silari circa ilicibusque virentem
    Plurimus Alburnum volitans, cui nomen asilo
    Romanum est, Oestrum Graii vertere vocantes,
    Asper, acerba sonans; quo tota exterrita silvis
    Diffugiunt armenta; furit mugitibus aether
    Concussus, sylvaeque et sicci ripa Tanagri.

                                    _Georg._ lib. iii. 146.

[GL] Linnaeus, Lachesis Lapponica, July 19th.

[GM] Linnaeus, Flora Lapponica, p. 378, ed. Lond. 1792.

[GN] Kirby and Spence, Introd. i. 151.

[GO] Kirby and Spence, p. 149.

[GP] These circumstances afford, we think, a complete answer to
the query of Kirby and Spence--"There can be little doubt (or else
what is the use of such an apparatus?) that it bores a hole in the
skin."--Introd. i. 162, 2nd edit.

[GQ] Linn. Trans. iii. 305.

[GR] Linn. Trans. iii. 305.

[GS] Mem. iv. 540.

[GT] Reaumur, iv. 549.

[GU] Bruce's Travels, i. 5, and v. 191.




Transcriber's Note

The unmatched opening quote on page 12 was assumed to be a
typographical error and removed. Where a sequential series of
paragraphs have an opening bracket without a closing one, these were
standardized to one opening and one closing bracket for the whole
section. One opening bracket missing on page 38 was assumed to belong
at the start of last line of that paragraph. The closing quote from the
second paragraph on page 47 was added. An Internet search confirmed
this location.

Where the footnotes originally stated "Ibid.", the source of the
previous footnote was inserted.







End of the Project Gutenberg EBook of Insect Architecture, by James Rennie

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