index_freq.html

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    <div class="chromo_popup overlay_info" id="moreinfo-dust_overlay">
      <h4 class="info">Dust</h4>
      <img  src="Dust_cut_small.jpg">
      <p>Most of the dust seen by Planck is very cold, at temperatures
	as low as around &minus;260 C, and as a result glows in
	Planck's high frequencies (particularly 353 GHz and above). It
	is cold, dense clumps of dust and gas that mark the earliest
	stages of the birth of stars.</p><p>Although the dust is
	concentrated in the disc of our Galaxy, Planck has mapped its
	distribution all over the sky, showing structure at high
	Galactic latitudes (looking up or down out of the plane) of
	the Galaxy. Many other galaxies also contain similar dust, but
	most of them have been removed from the map of dust shown
	here.</p><p>The emission from the dust seen by Planck must be
	removed from the maps before cosmological analysis, but is of
	great interested to astronomers studying star formation in our
	own Milky Way.</p>
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    <div class="chromo_popup overlay_info" id="moreinfo-dustpol_overlay">
      <h4 class="info">Dust Polarisation</h4>
      <img  src="Dustpol_cut_small.jpg">
      <p>The cold dust grains in our galaxy are aligned to the
	magnetic field, and this causes the light it emits to be
	slightly polarised. The direction of this polarisation tells us
	the orientation of the Galaxy's magnetic field.</p>
	<p>The texture used to display the polarisation direction was
	originally produced by Marc-Antoine Meville-Deschenes (IAS
	Paris).</p>
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    <div class="chromo_popup overlay_info" style="display:none" id="moreinfo-low_overlay">
      <h4 class="info">Low frequency foregrounds</h4>
      <img  src="Low_cut_small.jpg">
      <p>The "low frequency" foregrounds include a number of types
	of emission. Most of it is due to high energy electrons
	moving through the Galactic magnetic field (a phenomenon
	called "synchtrotron emission", and the rest is
	predominantly the emission from slower electrons moving
	through hot, ionised gas (a phenomenon called
	"Bremsstrahlung" or "free-free" emission). These phenomena
	cause strong emission at Planck's lowest frequencies
	(particularly 70 GHz and below). Most of the emission if
	located along the plane of our Galaxy, with the other bright
	spots primarily being galaxies beyond our own.</p><p>A small
	fraction of the microwave light is not accounted for by
	either of these methods, and is called "anomalous microwave
	emission". Planck has previously given a great deal of
	weight to the favoured theory, in which this enomalous
	emission is from tiny particles of dust spinning billions of
	times per second.</p><p>All of this emission is removed from
	the maps before the cosmological analysis, but it is of
	great interest to astronomers investigating the properties
	of our own Galaxy. With more analysis, and the inclusion of
	more information from other experiments, it should be
	possible to separate this single "foreground" into its
	constituent components.</p>
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    <div class="chromo_popup overlay_info" style="display:none" id="moreinfo-syncpol_overlay">
      <h4 class="info">Synchrotron Polarisation</h4>
      <img  src="syncpol_cut_small.jpg">
      <p>The "low frequency" foregrounds include a number of types of
	emission. Most of it is due to high energy electrons moving
	through the Galactic magnetic field (a phenomenon called
	"synchtrotron emission", and the rest is predominantly the
	emission from slower electrons moving through hot, ionised gas
	(a phenomenon called "Bremsstrahlung" or "free-free"
	emission). These phenomena cause strong emission at Planck's
	lowest frequencies (particularly 70 GHz and below). Most of
	the emission if located along the plane of our Galaxy, with
	the other bright spots primarily being galaxies beyond our
	own.A small fraction of the microwave light is due to tiny
	dust grains, spinning billions of times per second.</p><p>Of
	these three mechanisms, the synchroton emission is polarised,
	as the light is oriented to the direction of the magnetic
	field. This means that the synchroton emission maps out the
	magnetic field in our galaxy projected onto the sky, though
	the 3D structure is harder to deduce.</p><p>In the
	"colourised" version of the polarisation image the
	polarisation direction is indicated by the magnetic field
	direction (red = vertical, blue = horizontal).</p><p>The
	colourised image was made by Paddy Leahy (University of
	Manchester).</p>
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	<h4 class="info">Carbon Monoxide</h4>
      <img  src="CO_cut_small.jpg">
	<p>Most of the cold gas in our Galaxy is made of hydrogen,
	  which only shines brightly at the frequencies seen by Planck
	  when it is very hot. However, there are other "tracer" gases
	  that do emit light at appropriate frequencies, such as
	  carbon monoxide (CO). By carefully looking for the signs of
	  emission by CO at 115, 230 and 345 GHz, Planck has produced
	  the best all-sky map of this gas throughout our
	  Galaxy.</p><p>The carbon monoxide is, as expected, largely
	  concentrated in the Galactic Plane, though there are a
	  number of molecular clouds which shine brightly at these
	  frequencies. Planck's sensititivity has allowed it to detect
	  some very diffuse clouds that had not been seen
	  before.</p><p>The dark regions near the ecliptic poles are
	  because Planck's maps are more sensitive in these regions,
	  reducing the noise, or "graininess", in the images. The
	  emission from carbon monoxide must be removed from Planck's
	  maps before the comsological analysis, since any
	  contamination could skew the results.</p>
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    <div class="chromo_popup overlay_info" style="display:none" id="moreinfo-mask_cosm">
      <h4 class="info">Sky Mask</h4>
      <img  src="Maskpol_cut_small.jpg">
      <p>To do the cosmological analysis, any "contamination" from
	sources of light other than the CMB (primarily our Galaxy and
	others) must be removed. Although the Planck data can be used
	to make maps of the various other sources of light and correct
	for it, this is much more difficult to do in the centre of our
	Galaxy, and near the brightest sources of light around the
	rest of the sky. The "sky mask" shows the areas of sky that
	are not considered when doing the cosmological analysis, with
	those expluded from just the polarisation analysis shown in
	grey.</p>
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    <div class="chromo_popup overlay_info" style="display:none" id="moreinfo-ptsrc">
      <h4 class="info">Compact Sources</h4>
      <img  src="PtSrc_cut_small.jpg">
      <p>As well as the light from the Cosmic Microwave Background, and from diffuse dust annd gas in our own Galaxy, Planck also sees seemingly small objects dotted all over the sky. Some of these really are small, such as clumps of gas and dust in the process of forming stars. But others are simply very far away, such as other galaxies.</p>
      <p>The map of sources shown here is representative of the full range of sources, showing those seen at frequencies of 30GHz (red), 143 GHz (green) and 857 GHz (blue). The size of the dots is a measure of Planck's resolution at the different frequencies (the resolution is better at higher frequencies).</p>
      <p>The 30GHz sources are distributed over the whole sky, indicating that they are generally distant galaxies. The galaxies seen by Planck at this frequency are emitting large amounts of radio waves, often due to the activity of the central black hole.</p>
      <p>By contrast, the sources seen at 857 GHz are concentrated in the plane of our Galaxy, with a few in the Large and Small Magellanic Clouds and the Andromeda Galaxy (add the "Labels" to see where these are. These are clumps of dust, either in our Galaxy or in nearby ones.</p>
      <p>To do the comological analysis, most of these source have to be taken into account, either by ignoring that relevant patch of the sky (see the "Sky Mask") or by carefully removing the light associated with each source from the data before the full analysis is performed.</p>
    </div>

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      <h4 class="info">Lensing</h4>
      <img  src="Lens_cut_small.jpg">
      <p>As the light from the CMB travelled through the Universe
	over the course of 13.8 billion years, most of it has been
	completely unimpeded. But there are very subtle effects caused
	by concentrations of mass in the Universe - most of which is
	in the form of mysterious dark matter. The gravitational pull
	of the mass distorts the image of the CMB, and these
	distortions can be mapped over the sky. These distortions are
	shown here, with large concentrations of mass showing up
	brighter.</p>
      <p>The analysis depends on the assumptions about the patterns in
	the Cosmic Microwave Background itself, namely that on average
	all the hot-spots and cold-spots are circular. While that is
	true when averaging over the whole sky, it might not be the
	case when averaging over smaller regions, and some of the
	distortions are due to inherent variations in the original CMB
	light. There are also regions, particlarly in the Galactic
	Plane, but also around a few other objects, where the
	foregound light is so strong that it is not possible to
	calculate the mass distribution.</p>
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