-
Notifications
You must be signed in to change notification settings - Fork 153
/
HEMCO_Config.rc.CO2
741 lines (684 loc) · 49.3 KB
/
HEMCO_Config.rc.CO2
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
#------------------------------------------------------------------------------
# Harmonized Emissions Component (HEMCO) !
#------------------------------------------------------------------------------
#BOP
#
# !MODULE: HEMCO_Config.rc
#
# !DESCRIPTION: Contains configuration information for HEMCO. Define the
# emissions inventories and corresponding file paths here. Entire
# configuration files can be inserted into this configuration file with
# an '>>>include' statement, e.g. '>>>include HEMCO\_Config\_test.rc'
# The settings of include-files will be ignored.
#\\
#\\
# !REMARKS:
# This file has been customized for the CO2 simulation.
# See The HEMCO User's Guide for file details:
# http://wiki.geos-chem.org/The_HEMCO_User%27s_Guide
#
# !REVISION HISTORY:
# See https://github.com/geoschem/geos-chem for complete history
#EOP
#------------------------------------------------------------------------------
#BOC
###############################################################################
### BEGIN SECTION SETTINGS
###############################################################################
ROOT: ${RUNDIR_DATA_ROOT}/HEMCO
GCAPSCENARIO: ${RUNDIR_GCAP2_SCENARIO}
GCAPVERTRES: ${RUNDIR_GCAP2_VERTRES}
Logfile: *
DiagnPrefix: ./OutputDir/HEMCO_diagnostics
DiagnFreq: Monthly
Wildcard: *
Separator: /
Unit tolerance: 1
Negative values: 2
Only unitless scale factors: false
Verbose: false
VerboseOnCores: root # Accepted values: root all
### END SECTION SETTINGS ###
###############################################################################
### BEGIN SECTION EXTENSION SWITCHES
###############################################################################
# ExtNr ExtName on/off Species Years avail.
0 Base : on *
# ----- MAIN SWITCHES ---------------------------------------------------------
--> EMISSIONS : true
--> METEOROLOGY : true ${RUNDIR_MET_AVAIL}
--> CHEMISTRY_INPUT : true
# ----- RESTART FIELDS --------------------------------------------------------
--> GC_RESTART : true
# ----- GLOBAL INVENTORIES ----------------------------------------------------
--> FOSSIL_ODIAC : true # 2000-2018
--> FOSSIL_CDIAC : false # 1980-2014
--> OCEAN_EXCH_TAKA09 : false # 2000
--> OCEAN_EXCH_SCALED : true # 2000-2013
--> BBIO_DIURNAL : false # 1985
--> BBIO_SIB3 : true # 2006-2010
--> NET_TERR_EXCH : true # 2000
--> CO2CORR : true # 2000-2018
# ----- AIRCRAFT EMISSIONS ----------------------------------------------------
# There are 3 switches:
#
# 1. AEIC2019_DAILY selects daily AEIC 2019 emissions. For most simulations,
# this is not recommended due to the amount of computational overhead
# that will be incurred in regridding. But this may be useful for
# research purposes. Recommended setting: "AEIC2019_DAILY: false".
#
# 2. AEIC2019_MONMEAN selects monthly-mean AEIC 2019 emisisons, which will
# incur much less computational overhaead. This options should suffice
# for most simulations. Recommended setting "AEIC2019_MONMEAN: true".
#
# 3. AEIC_SCALE_1990_2019: If "false", the AEIC 2019 data from the year
# 2019 alone will be used. This will yield a "best estimate" of
# aviation emisssion. This could be important because simply scaling
# aviation emissions up and down is rather nonphysical. But if
# AEIC_SCALE_1990_2019 is set to true, then aviation emissions for
# 1990 to 2019 are estimated by:
#
# a. Scaling ALL aviation emissions based on the growth in fuelburn
# from 1990 to 2019* estimated by Lee et al. (2021); and
#
# b. Scaling aviation NOx emissions by an additional factor to reflect
# the changes in the NOx emissions index over the same period as
# reported by Lee et al. (2021).
#
# Recommended setting: "AEIC_SCALE_1990_2019: true"
#
# See additional notes in the AEIC scale factor section below.
#------------------------------------------------------------------------------
--> AEIC2019_DAILY : false # 2019 (daily data)
--> AEIC2019_MONMEAN : true # 2019 (monthly-mean data)
--> AEIC_SCALE_1990_2019 : true # Scale to year in 1990-2019
# ----- SHIP EMISSIONS --------------------------------------------------------
--> SHIP : true
--> CEDS_SHIP : true # 1750-2014
--> ICOADS_SHIP : false # 2004
# ----- NON-EMISSIONS DATA ----------------------------------------------------
--> CO2_COPROD : true # 2004-2009
--> OLSON_LANDMAP : true # 1985
--> YUAN_MODIS_LAI : true # 2000-2020
# -----------------------------------------------------------------------------
111 GFED : on CO2/CO2bb
--> GFED4 : true
--> GFED_daily : true
--> GFED_3hourly : false
--> Scaling_CO : 1.05
--> Scaling_NAP : 2.75e-4
--> hydrophilic BC : 0.2
--> hydrophilic OC : 0.5
--> fraction POG1 : 0.49
114 FINN : off CO2/CO2bb
--> FINN_daily : true
--> Scaling_CO : 1.0
--> hydrophilic BC : 0.2
--> hydrophilic OC : 0.5
### END SECTION EXTENSION SWITCHES ###
###############################################################################
### BEGIN SECTION BASE EMISSIONS
###############################################################################
# ExtNr Name sourceFile sourceVar sourceTime C/R/E SrcDim SrcUnit Species ScalIDs Cat Hier
(((EMISSIONS
#==============================================================================
# --- FOSSIL FUEL EMISSIONS ---
#
# National CO2 fossil fuel emissions exclude international shipping and aviation
# Carbon Dioxide Information Analysis Center (CDIAC) 1x1 national emissions
# (Andres et al., 2011)
# Open-source Data Inventory of Anthropogenic CO2 (ODIAC) 1x1 national emissions
# (Oda & Maksyutov, 2011)
#
# ---> Recommended option: ODIAC (set FOSSIL_ODIAC = true)
# ODIAC updated to v2019 by J. Fisher and Y. Cao, 12/2019
#==============================================================================
(((FOSSIL_CDIAC
0 FOSSILCO2_CDIAC $ROOT/CO2/v2014-09/FOSSIL/CDIAC_v2014.monthly.generic.1x1.nc CO2 1980-2014/1-12/1/0 C xy kg/m2/s CO2 40/41/80 1 1
0 FOSSILCO2FF_CDIAC - - - - - - CO2ff 40/41/80 1 1
)))FOSSIL_CDIAC
(((FOSSIL_ODIAC
0 FOSSILCO2_ODIAC $ROOT/CO2/v2022-11/FOSSIL/ODIAC_CO2.monthly.generic.1x1.nc CO2 2000-2018/1-12/1/0 C xy kg/m2/s CO2 40/41/80 1 2
0 FOSSILCO2FF_ODIAC - - - - - - CO2ff 40/41/80 1 2
)))FOSSIL_ODIAC
#==============================================================================
# --- OCEAN EXCHANGE EMISSIONS ---
#
# Ocean uptake/emission from Takahashi et al. (2009) and earlier works.
# Climatological exchange for 2000 (-1.4 PgC/yr) or scaled ocean exchange, which
# accounts for changing atmospheric CO2 (as in the paper) are now available.
#
# ---> Recommended option: scaled ocean exchange (set OCEAN_EXCH_SCALED = true)
#==============================================================================
(((OCEAN_EXCH_TAKA09
0 OCEANCO2_TAKA_ANNUAL $ROOT/CO2/v2022-11/OCEAN/Taka2009_CO2_Annual.nc CO2 2000/1/1/0 C xy kg/m2/s CO2 - 2 1
0 OCEANCO2OC_TAKA_ANNUAL - - - - - - CO2oc - 2 1
0 OCEANCO2_TAKA_MONTHLY $ROOT/CO2/v2022-11/OCEAN/Taka2009_CO2_Monthly.nc CO2 2000/1-12/1/0 C xy kg/m2/s CO2 - 2 2
0 OCEANCO2OC_TAKA_MONTHLY - - - - - - CO2oc - 2 2
)))OCEAN_EXCH_TAKA09
(((OCEAN_EXCH_SCALED
0 OCEANCO2_SCALED_MONTHLY $ROOT/CO2/v2022-11/OCEAN/Scaled_Ocean_CO2_monthly.nc CO2 2000-2013/1-12/1/0 C xy kg/m2/s CO2 - 2 3
0 OCEANCO2OC_SCALED_MONTHLY - - - - - - CO2oc - 2 3
)))OCEAN_EXCH_SCALED
#==============================================================================
# --- BALANCED BIOSPHERE EXCHANGE ---
#
# These emissions have a seasonal cycle of uptake/emission but have a net
# annual uptake of close to zero (balanced).
# CASA model daily emissions for a single year at coarse resolution have a
# diurnal cycle imposed (Olsen & Randerson, 2004)
# SiB3 emissions are from Nick Parazoo (Messerschmidt et al., 2011) for
# 2006-2010.
#
# ---> Recommended option: SiB3 (set BBIO_SIB3 = true)
#==============================================================================
(((BBIO_DIURNAL
0 BBIOCO2_DIURNAL $ROOT/CO2/v2014-09/BBIO/BBIO_diurnal_CO2.nc CO2 1985/1-12/1-31/0-23 C xy kg/m2/s CO2 - 3 1
0 BBIOCO2BAL_DIURNAL - - - - - - CO2bal - 3 1
)))BBIO_DIURNAL
(((BBIO_SIB3
0 SIB_BBIO_CO2 $ROOT/CO2/v2022-11/BIO/SiB3_3hr_NEP.nc CO2 2006-2010/1-12/1-31/0-23 C xy kg/m2/s CO2 - 3 1
0 SIB_BBIO_CO2BAL - - - - - - CO2bal - 3 1
)))BBIO_SIB3
#==============================================================================
# --- NET TERRESTRIAL EXCHANGE ---
#
# TransCom annual net/residual terrestrial biosperhic CO2 (Baker et al., 2006)
#
# ---> Recommended for use in forward modelling, optional for
# inversion/assimilation
#==============================================================================
(((NET_TERR_EXCH
0 CO2_NET_TERRESTRIAL $ROOT/CO2/v2022-11/BIO/Net_terrestrial_exch_5.29Pg.generic.1x1.nc CO2 2000/1/1/0 C xy kg/m2/s CO2nte - 5 1
0 CO2NTE_NET_TERRESTRIAL - - - - - - CO2 - 5 1
)))NET_TERR_EXCH
#==============================================================================
# --- SHIP EMISSIONS ---
#==============================================================================
(((SHIP
(((ICOADS_SHIP
# The spatial distribution is scaled with global annual scale factors #50
0 ICOADS_CO2_SHIP $ROOT/ICOADS_SHIP/v2014-07/ICOADS_ship_CO2_2004.generic.1x1.nc CO2 2004/1-12/1/0 C xy kg/m2/s CO2 50 6 1
0 ICOADS_CO2SE_SHIP - - - - - - CO2se 50 6 1
)))ICOADS_SHIP
(((CEDS_SHIP
0 CEDS_CO2_SHP $ROOT/CEDS/v2021-06/$YYYY/CO2-em-anthro_CMIP_CEDS_$YYYY.nc CO2_shp 1750-2019/1-12/1/0 C xy kg/m2/s CO2 - 6 1
0 CEDS_CO2SE_SHIP - - - - - - CO2se - 6 1
)))CEDS_SHIP
)))SHIP
#==============================================================================
# --- AEIC 2019 aircraft emissions ---
#
# Data files are for 2019, but scale factors from 1990-2019 can be applied
# in order to get year-specific emissions. See the notes in the AEIC2019
# scale factor section below for more information.
#==============================================================================
(((AEIC2019_DAILY
0 AEIC19_DAILY_CO2 $ROOT/AEIC2019/v2022-03/2019/AEIC_2019$MM$DD.0.5x0.625.36L.nc FUELBURN 2019/1-12/1-31/0 C xyz kg/m2/s CO2 241/60 20 1
0 AEIC19_DAILY_CO2AV - - - - - - CO2av 241/60 20 1
)))AEIC2019_DAILY
(((AEIC2019_MONMEAN
0 AEIC19_MONMEAN_CO2 $ROOT/AEIC2019/v2022-03/2019_monmean/AEIC_monmean_2019$MM.0.5x0.625.36L.nc FUELBURN 2019/1-12/1/0 C xyz kg/m2/s CO2 241/60 20 1
0 AEIC19_MONMEAN_CO2AV - - - - - - CO2av 241/60 20 1
)))AEIC2019_MONMEAN
#==============================================================================
# --- CO2 SURFACE CORRECTION FOR CO OXIDATION ---
#
# These emissions will be subtracted!
# Fossil fuel CO and CH4 are based on the national distribution scaled with #10.
# Biogenic CH4 data is converted to CO2 using scale factor #20.
# Isoprene and monoterpene are converted from kgC to kgCO2 by scale factor #21.
# Approach is described in Nassar et al. (2010)
#
# ---> Recommended for use if chemical production (above) is turned on
#
# Now multiply by scale factor of -1.0 (#90 in scale factor section below)
# to make these emissions negative, so that they will be subtracted.
===============================================================================
(((CO2CORR
0 FOSSILCO2_MONTHLY $ROOT/CO2/v2022-11/FOSSIL/ODIAC_CO2.monthly.generic.1x1.nc CO2 2000-2018/1-12/1/0 C xy kg/m2/s CO2 10/40/41/80/90 8 1
0 FOSSILCO2CORR_MONTHLY - - - - - - CO2corr 10/40/41/80/90 8 1
0 CO2_LIVESTOCK $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_004 2004/1-12/1/0 C xy kg/m2/s CO2 20/90 8 1
0 CO2CORR_LIVESTOCK - - - - - - CO2corr 20/90 8 1
0 CO2_WASTE $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_005 2004/1-12/1/0 C xy kg/m2/s CO2 20/90 8 1
0 CO2CORR_WASTE - - - - - - CO2corr 20/90 8 1
0 CO2_RICE $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_007 2004/1-12/1/0 C xy kg/m2/s CO2 20/90 8 1
0 CO2CORR_RICE - - - - - - CO2corr 20/90 8 1
0 CO2_WETLANDS $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_010 2004/1-12/1/0 C xy kg/m2/s CO2 20/90 8 1
0 CO2CORR_WETLANDS - - - - - - CO2corr 20/90 8 1
0 CO2_NATURAL $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_012 2004/1-12/1/0 C xy kg/m2/s CO2 20/90 8 1
0 CO2CORR_NATURAL - - - - - - CO2corr 20/90 8 1
0 CO2_ISOPRENE $ROOT/CO2/v2022-11/CHEM/Isoprene-2004.geos.2x25.nc ISOP 2004/1-12/1/0 C xy kg/m2/s CO2 21/30/90 8 1
0 CO2CORR_ISOPRENE - - - - - - CO2corr 21/30/90 8 1
0 CO2_MONOTERP $ROOT/CO2/v2022-11/CHEM/Monoterpene-2004.geos.2x25.nc MONOT 2004/1-12/1/0 C xy kg/m2/s CO2 21/30/90 8 1
0 CO2CORR_MONOTERP - - - - - - - 21/30/90 8 1
)))CO2CORR
###############################################################################
### EXTENSION DATA (subsection of BASE EMISSIONS SECTION)
###
### These fields are needed by the extensions listed above. The assigned ExtNr
### must match the ExtNr entry in section 'Extension switches'. These fields
### are only read if the extension is enabled. The fields are imported by the
### extensions by field name. The name given here must match the name used
### in the extension's source code.
###############################################################################
#==============================================================================
# --- GFED biomass burning emissions (Extension 111)
# NOTE: These are the base emissions in kgDM/m2/s.
#==============================================================================
(((GFED4
111 GFED_TEMP $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_TEMP 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1
111 GFED_AGRI $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_AGRI 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1
111 GFED_DEFO $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_DEFO 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1
111 GFED_BORF $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_BORF 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1
111 GFED_PEAT $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_PEAT 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1
111 GFED_SAVA $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_SAVA 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1
(((GFED_daily
111 GFED_FRAC_DAY $ROOT/GFED4/v2023-03/$YYYY/GFED4_dailyfrac_gen.025x025.$YYYY$MM.nc GFED_FRACDAY 2010-2023/1-12/1-31/0 RF xy 1 * - 1 1
)))GFED_daily
(((GFED_3hourly
111 GFED_FRAC_3HOUR $ROOT/GFED4/v2023-03/$YYYY/GFED4_3hrfrac_gen.025x025.$YYYY$MM.nc GFED_FRAC3HR 2010-2023/1-12/1/0-23 RF xy 1 * - 1 1
)))GFED_3hourly
)))GFED4
#==============================================================================
# --- FINN v1.5 biomass burning emissions (Extension 114)
#==============================================================================
(((.not.FINN_daily
114 FINN_VEGTYP1 $ROOT/FINN/v2015-02/FINN_monthly_$YYYY_0.25x0.25.compressed.nc fire_vegtype1 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_VEGTYP2 $ROOT/FINN/v2015-02/FINN_monthly_$YYYY_0.25x0.25.compressed.nc fire_vegtype2 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_VEGTYP3 $ROOT/FINN/v2015-02/FINN_monthly_$YYYY_0.25x0.25.compressed.nc fire_vegtype3 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_VEGTYP4 $ROOT/FINN/v2015-02/FINN_monthly_$YYYY_0.25x0.25.compressed.nc fire_vegtype4 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_VEGTYP5 $ROOT/FINN/v2015-02/FINN_monthly_$YYYY_0.25x0.25.compressed.nc fire_vegtype5 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_VEGTYP9 $ROOT/FINN/v2015-02/FINN_monthly_$YYYY_0.25x0.25.compressed.nc fire_vegtype9 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
))).not.FINN_daily
(((FINN_daily
114 FINN_DAILY_VEGTYP1 $ROOT/FINN/v2015-02/FINN_daily_$YYYY_0.25x0.25.compressed.nc fire_vegtype1 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_DAILY_VEGTYP2 $ROOT/FINN/v2015-02/FINN_daily_$YYYY_0.25x0.25.compressed.nc fire_vegtype2 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_DAILY_VEGTYP3 $ROOT/FINN/v2015-02/FINN_daily_$YYYY_0.25x0.25.compressed.nc fire_vegtype3 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_DAILY_VEGTYP4 $ROOT/FINN/v2015-02/FINN_daily_$YYYY_0.25x0.25.compressed.nc fire_vegtype4 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_DAILY_VEGTYP5 $ROOT/FINN/v2015-02/FINN_daily_$YYYY_0.25x0.25.compressed.nc fire_vegtype5 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
114 FINN_DAILY_VEGTYP9 $ROOT/FINN/v2015-02/FINN_daily_$YYYY_0.25x0.25.compressed.nc fire_vegtype9 2002-2016/1-12/1/0 RF xy kg/m2/s * - 1 1
)))FINN_daily
)))EMISSIONS
###############################################################################
### NON-EMISSIONS DATA (subsection of BASE EMISSIONS SECTION)
###
### Non-emissions data. The following fields are read through HEMCO but do
### not contain emissions data. The extension number is set to wildcard
### character denoting that these fields will not be considered for emission
### calculation. A given entry is only read if the assigned species name is
### an HEMCO species.
###############################################################################
#==============================================================================
# --- Time zones (offset to UTC) ---
#==============================================================================
* TIMEZONES $ROOT/TIMEZONES/v2024-02/timezones_vohra_2017_0.1x0.1.nc UTC_OFFSET 2017/1-12/1/0 C xy count * - 1 1
#==============================================================================
# --- Meteorology fields ---
#==============================================================================
(((METEOROLOGY
>>>include ${RUNDIR_MET_FIELD_CONFIG}
)))METEOROLOGY
#==============================================================================
# --- GEOS-Chem restart file ---
#==============================================================================
(((GC_RESTART
* SPC_ ./Restarts/GEOSChem.Restart.$YYYY$MM$DD_$HH$MNz.nc4 SpeciesRst_?ALL? $YYYY/$MM/$DD/$HH EFYO xyz 1 * - 1 1
* DELPDRY ./Restarts/GEOSChem.Restart.$YYYY$MM$DD_$HH$MNz.nc4 Met_DELPDRY $YYYY/$MM/$DD/$HH EY xyz 1 * - 1 1
)))GC_RESTART
#==============================================================================
# --- CHEMICAL PRODUCTION FROM CO OXIDATION ---
#
# ---> Recommended for use in forward modelling, optional for
# inversion/assimilation
#==============================================================================
(((CHEMISTRY_INPUT
(((CO2_COPROD
${RUNDIR_CO2_COPROD}
)))CO2_COPROD
)))CHEMISTRY_INPUT
#==============================================================================
# --- Olson land map masks ---
#==============================================================================
(((OLSON_LANDMAP
* LANDTYPE00 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE00 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE01 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE01 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE02 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE02 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE03 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE03 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE04 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE04 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE05 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE05 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE06 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE06 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE07 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE07 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE08 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE08 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE09 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE09 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE10 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE10 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE11 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE11 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE12 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE12 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE13 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE13 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE14 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE14 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE15 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE15 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE16 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE16 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE17 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE17 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE18 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE18 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE19 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE19 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE20 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE20 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE21 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE21 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE22 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE22 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE23 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE23 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE24 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE24 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE25 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE25 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE26 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE26 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE27 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE27 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE28 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE28 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE29 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE29 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE30 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE30 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE31 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE31 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE32 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE32 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE33 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE33 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE34 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE34 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE35 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE35 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE36 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE36 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE37 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE37 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE38 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE38 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE39 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE39 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE40 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE40 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE41 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE41 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE42 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE42 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE43 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE43 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE44 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE44 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE45 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE45 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE46 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE46 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE47 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE47 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE48 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE48 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE49 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE49 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE50 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE50 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE51 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE51 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE52 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE52 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE53 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE53 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE54 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE54 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE55 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE55 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE56 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE56 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE57 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE57 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE58 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE58 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE59 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE59 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE60 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE60 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE61 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE61 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE62 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE62 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE63 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE63 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE64 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE64 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE65 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE65 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE66 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE66 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE67 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE67 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE68 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE68 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE69 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE69 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE70 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE70 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE71 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE71 1985/1/1/0 C xy 1 * - 1 1
* LANDTYPE72 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE72 1985/1/1/0 C xy 1 * - 1 1
)))OLSON_LANDMAP
#==============================================================================
# --- Yuan processed MODIS leaf area index data ---
#
# Source: Yuan et al 2011, doi:10.1016/j.rse.2011.01.001
# http://globalchange.bnu.edu.cn/research/lai
#
# NOTES:
# (1) LAI data corresponding to each Olson land type is stored in
# separate netCDF variables (XLAI00, XLAI01, ... XLAI72).
# The "XLAI" denotes that the files are prepared in this way.
# (2) Units are "cm2 leaf/cm2 grid box".
# (3) Data is timestamped every 8 days, starting from the 2nd of the month.
#==============================================================================
(((YUAN_MODIS_LAI
* XLAI00 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI00 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI01 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI01 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI02 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI02 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI03 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI03 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI04 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI04 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI05 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI05 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI06 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI06 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI07 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI07 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI08 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI08 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI09 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI09 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI10 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI10 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI11 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI11 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI12 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI12 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI13 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI13 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI14 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI14 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI15 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI15 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI16 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI16 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI17 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI17 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI18 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI18 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI19 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI19 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI20 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI20 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI21 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI21 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI22 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI22 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI23 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI23 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI24 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI24 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI25 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI25 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI26 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI26 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI27 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI27 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI28 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI28 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI29 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI29 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI30 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI30 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI31 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI31 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI32 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI32 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI33 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI33 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI34 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI34 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI35 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI35 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI36 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI36 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI37 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI37 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI38 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI38 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI39 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI39 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI40 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI40 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI41 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI41 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI42 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI42 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI43 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI43 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI44 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI44 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI45 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI45 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI46 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI46 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI47 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI47 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI48 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI48 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI49 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI49 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI50 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI50 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI51 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI51 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI52 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI52 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI53 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI53 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI54 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI54 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI55 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI55 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI56 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI56 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI57 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI57 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI58 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI58 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI59 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI59 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI60 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI60 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI61 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI61 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI62 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI62 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI63 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI63 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI64 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI64 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI65 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI65 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI66 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI66 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI67 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI67 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI68 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI68 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI69 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI69 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI70 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI70 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI71 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI71 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
* XLAI72 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI72 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1
)))YUAN_MODIS_LAI
### END SECTION BASE EMISSIONS ###
###############################################################################
### BEGIN SECTION SCALE FACTORS
###############################################################################
# ScalID Name sourceFile sourceVar sourceTime C/R/E SrcDim SrcUnit Oper
(((EMISSIONS
#==============================================================================
# --- FOSSIL FUEL CO2 SURFACE CORRECTION FACTOR ---
#
# Fossil fuel CO2 emissions must be scaled down to avoid counting emissions
# already accounted for by CO and CH4 oxidation to CO2.
#
# The necssary annual reduction in emissions related to fossil fuels is
# determined as: global C mass from FF (CO+CH4) / global C mass from FF CO2
#
# Note: GEOS-Chem v8-03-02 to v9-02, assumed: 0.0489 for all years but that
# value seems to correspond to mid-1980s fossil fuel combustion since CO
# emissions have held constant (Granier et al., 2011) while CO2 has risen.
#
#==============================================================================
(((CO2CORR
#10 CO2_FOSSFUEL_CORR 0.0489 - - - xy 1 1
## CO2 scale factors from CO oxidation by decade (comment out for now)
##10 CO2_FOSSFUEL_CORR 0.052815/0.054486/0.054902/0.055107/0.053166/0.051611/0.050065/0.048803/0.047060/0.046041 - 1980-1989/1/1/0 C xy 1 1
##10 CO2_FOSSFUEL_CORR 0.045816/0.045153/0.045541/0.045556/0.044800/0.043875/0.042910/0.042206/0.042257/0.042468 - 1990-1999/1/1/0 C xy 1 1
##10 CO2_FOSSFUEL_CORR 0.041495/0.040525/0.040125/0.037853/0.035957/0.034686/0.033538/0.032771/0.031961/0.032118 - 2000-2009/1/1/0 C xy 1 1
##10 CO2_FOSSFUEL_CORR 0.030622/0.029674/0.029029/0.028355 - 2010-2013/1/1/0 C xy 1 1
# All scale factors for years 2000-2013 lumped into a single entry
10 CO2_FOSSFUEL_CORR 0.041495/0.040525/0.040125/0.037853/0.035957/0.034686/0.033538/0.032771/0.031961/0.032118/0.030622/0.029674/0.029029/0.028355 - 2000-2013/1/1/0 C xy 1 1
)))CO2CORR
#==============================================================================
# --- CO2 CONVERSION FACTORS ---
#==============================================================================
20 CH4TOCO2 2.75 - - - xy 1 1
21 CTOCO2 3.6667 - - - xy 1 1
30 NMHCSCALE 0.3333 - - - xy 1 1
#==============================================================================
# ---- TIMES diurnal and weekly scale factors for national fossil fuel CO2 ---
#
# These temporal scale factors are described in Nassar et al. (2013)
#==============================================================================
(((FOSSIL_CDIAC.or.FOSSIL_ODIAC.or.CO2CORR
40 CO2_DIURNAL $ROOT/CO2/v2015-04/FOSSIL/TIMES_diurnal_scale_factors.nc diurnal_scale_factors 2006/1/1/1-24 C xy 1 1
41 CO2_WEEKLY $ROOT/CO2/v2015-04/FOSSIL/TIMES_weekly_scale_factors.nc weekly_scale_factors 2006/1/WD/0 C xy 1 1
)))FOSSIL_CDIAC.or.FOSSIL_ODIAC.or.CO2CORR
#==============================================================================
# --- SHIP ANNUAL SCALE FACTOR ---
#
# Based on a linear fit of 1985-2002 values from Endresen et al. (2007).
#==============================================================================
(((ICOADS_SHIP
50 CO2_SHIP_SCALE 1.043/1.068/1.094/1.128/1.154/1.180/1.205/1.231/1.265/1.291/1.316/1.342/1.368/1.393/1.427/1.453/1.479/1.504/1.530/1.556/1.590/1.615/1.641/1.667/1.641 - 1985-2009/1/1/0 C xy 1 1
)))ICOADS_SHIP
#==============================================================================
# --- AEIC2019 aircraft emissions scale factors ---
#
# See http://geoschemdata.wustl.edu/ExtData/HEMCO/AEIC2019/v2022-03/AEIC_2019_technical_note.pdf
#==============================================================================
(((AEIC2019_DAILY.or.AEIC2019_MONMEAN
#------------------------------------------------------------------------------
# Assume 3.159 kg CO2 from every kg of fuel burned
# cf Hileman, Stratton, & Donohoo, _J. Propul. Power_, 26(6), 1184–1196, 2010.
#------------------------------------------------------------------------------
60 AEIC19_FBtoCO2 3.159 - - - xy unitless 1
#------------------------------------------------------------------------------
# Scaling factors for 1990-2019 derived from Lee et al. (2021). Lee et al.
# (2021) only covers 1990 to 2018, so to get to 2019 it is assumed that the
# growth from 2017 to 2018 is the same as that from 2018 to 2019.
# So the formula is something like:
#
# Emissions of CO in 2009 = AEIC 2019 emissions of CO
# * (Lee 2017 CO / Lee 2018 fuel burn)
# * (Lee 2009 fuel burn / Lee 2018 fuel burn)
#
# So in this case, we use the Lee 2017/Lee 2018 value to scale AEIC’s
# emissions to the “2018” values, and then scale directly using the Lee et al
# fuel burn. This ensures that, when running with year 2019, you get an
# unadjusted version of the AEIC2019 inventory, and all previous years are
# scaled down.
#
# All scaling factors are included in here in HEMCO_Config.rc.
#------------------------------------------------------------------------------
(((AEIC_SCALE_1990_2019
241 AC_FBMULT 0.506/0.489/0.490/0.493/0.517/0.529/0.553/0.570/0.581/0.600/0.631/0.607/0.608/0.608/0.646/0.678/0.686/0.706/0.703/0.666/0.700/0.721/0.728/0.749/0.773/0.815/0.854/0.905/0.952/1.000 - 1990-2019/1/1/0 C xy 1 1
)))AEIC_SCALE_1990_2019
# If not applying 1990-2019 scale factors, use 1.0
(((.not.AEIC_SCALE_1990_2019
241 AC_FBMULT 1.000000e+0 - - - xy 1 1
))).not.AEIC_SCALE_1990_2019
)))AEIC2019_DAILY.or.AEIC2019_MONMEAN
#==============================================================================
# --- DOMESTIC AVIATION SURFACE CORRECTION FACTOR ---
#
# Regional scale factors slightly less than 1 remove surface contribution from
# domestic aviation in national fossil fuel emisisons, which should instead be
# counted in the air as a 3D field. This scale factor should be applied to the
# main/national fossil fuel emission field if using avaition emissions.
#==============================================================================
(((FOSSIL_CDIAC.or.FOSSIL_ODIAC.or.CO2CORR
80 AVIATION_SURF_CORR $ROOT/CO2/v2015-04/FOSSIL/Aviation_SurfCorr_SclFac.1x1.nc CO2 2004/1/1/0 C xy 1 1
)))FOSSIL_CDIAC.or.FOSSIL_ODIAC.or.CO2CORR
#==============================================================================
# Scale factor to make emissions negative
#==============================================================================
(((CO2CORR
90 CO2_NEGATIVE -1.0 - 2000/1/1/0 C xy 1 1
)))CO2CORR
)))EMISSIONS
### END SECTION SCALE FACTORS ###
###############################################################################
### BEGIN SECTION MASKS
###############################################################################
# ScalID Name sourceFile sourceVar sourceTime C/R/E SrcDim SrcUnit Oper Lon1/Lat1/Lon2/Lat2
### END SECTION MASKS ###
###############################################################################
### REFERNCES
###############################################################################
#
# Andres. R.J., J.S Gregg, L. Losey, G. Marland, T.A. Boden (2011), Montly,
# global emissions of carbon dioxide from fossil fuel consumption, Tellus 63B,
# 309-327.
#
# Baker, D.F. et al. (2006) TransCom3 inversion intercomparison: Impact of
# transport model errors on the interannual variability of regional CO2 fluxes,
# 1998-2003, Global Biogeochem., Cy., 20, GB1002, doi:10.29/2004GB002439.
#
# Endresen, O. et al. (2007), A historical reconstuctino of ships fuel
# consuption and emissions, J. Geophys. Res., 112, D12301,
# doi:10.1029/2006JD007630.
#
# Granier, C. et al. (2011), Evolution of anthropogenic and biomass burning
# emissions of air pollutants at global and regional scales during the 1980-2010
# period, Climatic Change, 109:163-190, doi:10.1007/s10584-011-0154-1.
#
# Keller, C.A., M.S. Long, R.M. Yantosca, A.M. DaSilva, S. Pawson, D.J. Jacob
# (2014), HEMCO v1.0: a versatile, ESMF-compliant component for calculating
# emissions in atmospheric models, Geosci., Model Dev., 7, 1409?1417,
# doi:10.5194/gmd-7-1409-2014.
#
# Messerschmidt, J., N. Parazoo, N.M. Deutscher, C. Roehl, T. Warneke, P.O.
# Wennberg, and D. Wunch (2012) Evaluation of atmosphere-biosphere exchange
# estimations with TCCON measurements, Atmos. Chem. Phys. Discussions, 12,
# 12759-12800, doi:10.5194/acpd-12-12759-2012.
#
# Nassar, R., D.B.A. Jones, P. Suntharalingam, J.M. Chen, R.J. Andres, K.J.
# Wecht, R.M. Yantosca, S.S. Kulawik, K.W. Bowman, J.R. Worden, T. Machida and
# H. Matsueda (2010), Modeling global atmospheric CO2 with improved emission
# inventories and CO2 production from the oxidation of other carbon species,
# Geoscientific Model Development, 3, 689-716.
#
# Nassar, R., L. Napier-Linton, K.R. Gurney, R.J. Andres, T. Oda, F.R. Vogel,
# F. Deng (2013), Improving the temporal and spatial distribution of CO2
# emissions from global fossil fuel emission datasets, Journal of Geophysical
# Research: Atmospheres, 118, 917-933, doi:10.1029/2012JD018196.
#
# Oda, T. and S. Maksyutov (2011), A very high-resolution (1 km x 1 km) global
# fossil fuel CO2 emission inventory derived using a point source database and
# satellite observations of nighttime lights, Atmos. Chem. Phys., 11, 543?556,
# doi:10.5194/acp-11-543-2011.
#
# Olsen, S.C. and J.T. Randerson (2004), Differences between surface and column
# atmospheric CO2 and implications for carbon cycle research, J. Geophys. Res.
# 109, D02301, doi:10.1029/2003JD003968.
#
# Olsen, S.C., D.J. Weubbles, B. Owen (2013) Comparison of global 3-D aviation
# datasets, Atmos. Chem. Phys., 13, 429?441, doi:10.5194/acp-13-429-2013.
#
# Simone, N., M. Stettler, S. Eastham, S. Barrett, Aviation Emissions Inventory
# Code (AEIC ) User Manual (R1), Laboratory for Aviation and the Environment,
# Massachusetts Institute of Technology, January 2013, Report No:
# LAE-2013-001-N,
# www.LAE.MIT.edu.
#
# Takahashi, T., et al. (2009), Climatological mean and decadal change in
# surface ocean pCO2, and net sea-air CO2 flux over the global oceans, Deep-Sea
# Res. II, 56(8?10), 554?577, doi:10.1016/j.dsr2.2008.12.009.
#
### END OF HEMCO INPUT FILE ###
#EOC