galaxy formation & evolution: the sub-mm view james dunlop
DESCRIPTION
Galaxy formation & evolution: the sub-mm view James Dunlop. Outline. 0. Why? 1. Surveys and number counts 2. Identifications and redshifts 3. Sizes, morphologies and masses 4. The nature of sub-mm galaxies 5. Future prospects. 1. Surveys and number counts. SHADES. DATA - PowerPoint PPT PresentationTRANSCRIPT
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Galaxy formation & evolution:Galaxy formation & evolution:the sub-mm viewthe sub-mm view
James Dunlop
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Outline
0. Why?
1. Surveys and number counts
2. Identifications and redshifts
3. Sizes, morphologies and masses
4. The nature of sub-mm galaxies
5. Future prospects
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1. Surveys and number counts1. Surveys and number counts
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SHADES
• SCUBA 850-micron map of ~1/4 sq. degrees
• 850 rms ~2 mJy
• Two fields – Lockman Hole & SXDF
• Major multi-frequency follow-up
VLA, GMRT, UKIRT, Spitzer, Subaru, Keck, Gemini, VLT, AAT,
XMM, Chandra, SMA, AzTEC
DATA
3 years observing with an increasingly ill SCUBA
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SHADES SCUBA 850-micron maps2 fields – Lockman Hole & SXDF/UDS
4 independent reductions combined to produce one SHADES catalogue
120 sources with unbiased (deboosted) flux densities
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Number counts
Coppin et al. 2006
Estimated background of sources >2mJy is ~9700 mJy/deg2
>20-30% of FIRB resolved
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New SHADES AzTEC 1.1mm maps(SNR maps shown here produced by Jason Austerman)
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850-micron contours on 1.1mm greyscale
Joint SCUBA+AzTEC source extraction now being explored
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2. Identifications and redshifts2. Identifications and redshifts
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Radio and mid-infraredRadio and mid-infrared
Ivison et al., (2007)
25 x 25 arcsec stamps
VLA radio contours on
R-band Subaru image, and
Spitzer 24-micron image
85-90% of the 120 sources identified via VLA and/or Spitzer
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Sometimes identification can be tricky
e.g. SMA follow-up of SXDF850.6 Iono et al. (2008)
VLA 1.4 GHz Optical - Subaru
SMA
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Finally …….unambiguous K-band ID
SMA on optical SMA on K-band
Demonstrates
1. power of sub-mm interferometry
2. importance of near-IR data identification & study of host galaxy
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SMA – a glimpse of ~1 arcsec sub-mm astronomySMA – a glimpse of ~1 arcsec sub-mm astronomy
Younger et al. (2007)
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Redshifts
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RedshiftsRedshifts
4 different forms of redshift information:
• Spectroscopic – Chapman et al., Stevens et al.
• Far-infrared to radio – Carilli & Yun, Aretxaga et al.
• Optical – near-infrared – Dye et al., Clements et al.
• Spitzer – Pope et al.
In SHADES only ~12 (ie 10%) of sources currently have an unambiguous spectroscopic z
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e.g. Clements et al. (2008)
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GOODS 850.5 – Wang et al. 2008
COSMOS AzTEC 1 – Younger et al. 2007
GN20 – Iono et al. 2006Younger et al. 2008
SFR > 1000 Msun yr -1
SFR > 2000 Msun yr -1
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Evidence of down-sizing:
Clear that the comoving number density of > 5 mJy sub-mm sources peaks in redshift range 2 < z < 3
Brightest (>12 mJy) sources lie at 3 < z < 4
< 5mJy sources span much wider z range
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Number densities at 2 < z < 3
Mstar >1011 Msun : 1 x 10-4 Mpc-3
SFR > 500 Msun yr -1 : 2 x 10-5 Mpc-3
SFR > 1000 Msun yr -1 : 3 x 10-6 Mpc-3
SFR > 2000 Msun yr -1 : 1 x 10-6 Mpc-3
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3. Sizes, morphologies, masses3. Sizes, morphologies, masses
Some new results from
Targett, Dunlop, et al. (2008)
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Deep, high-resolution (0.4 arcsec) K-band imaging of 13 radio galaxies and 15 8-mJy sub-mm galaxies at z ~ 2
Radio galaxies
= known elliptical progenitors
Sub-mm galaxies
= possible elliptical progenitors
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Results from galaxy model fitting
Sizes Kormendy relation at z = 2
Sub-mm galaxies
Radio galaxies
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Morphologies
Sub-mm galaxies are mainly discs
Radio galaxies are r1/4 spheroids
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Image Stack
~50 hr UKIRT image of z = 2 radio galaxy
~20 hr Gemini image of z = 2 submm galaxy
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MassesMasses
CO dynamical masses suggest
~1011 Msun within r ~ 2 kpc (Tacconi et al. 2006)
We find typical stellar masses
~ 3 - 5 x 1011 Msun and typical r0.5 = 2-3 kpc
(See also Dye et al. 2008, and Wang et al 2008)
Await decent clustering measurements tocharacterize typical CDM halo masses of submm galaxies
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Stellar masses from 2-comp fittingStellar masses from 2-comp fitting
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4. The nature of sub-mm galaxies4. The nature of sub-mm galaxies
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4. The nature of sub-mm galaxies4. The nature of sub-mm galaxies
Sometimes claimed that sub-mm galaxies are bizarre objects in a very unusual phase/mode of star formation
But….
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You’d expect such a big starburst to be hosted by an already massive galaxy
Daddi et al. (2007)
SFR v stellar mass relation at z = 2
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…. and the massive host galaxy has a very high stellar mass density
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Sub-mm and radio galaxies in the mass-density : mass plane- following Zirm et al. (2006)
Sub-mm galaxies
Radio galaxies
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5. Future prospects5. Future prospects
Larger, deeper samples with complete SEDs
- BLAST, SCUBA2, Herschel, LMT, CCAT
Complete IR identifications, redshifts, masses
- UKIDSS, Ultra-VISTA, Spitzer, FMOS, KMOS
Detailed high-resolution spectroscopy
- ALMA, JWST
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Cosmology Legacy Survey
Jim Dunlop University of Edinburgh+ Ian Smail (Durham), Mark Halpern (UBC), Paul van der Werf (Leiden)
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SCUBA-2 is a new CCD-style imager for the JCMT
50 sq arcmin FOV ~ 10 x SCUBA FOV
Cosmology Legacy Survey
Fully sampled imaging
New TES detectors
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SCUBA2 Survey Strategy
Cosmology Legacy Survey
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Wide 850 survey – “Super SHADES”
20 sq degrees, = 0.7 mJy ~10,000 sources with S/N > 10
• ~Schmidt plate in area, to the depth of the SCUBA HDF image
• Accurate measurements of clustering and redshift distribution – placing luminous starbursts within CDM
• Observing proto Coma clusters
• The bright source counts – extreme objects
• Bulge and black-hole formation
• Intermediate and low-redshift sources
• The SZ effect
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Deep 450 micron survey
0.6 sq degree, = 0.5 mJy, ~10000 sources
• Bolometric output of the 850 micron population
• Determining the source populations dominating the 450 micron background
• Exploiting high-resolution to beat down the confusion limit
• Exploiting high resolution to better identify the 850 micron sources + connect with Herschel and Spitzer data
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1. Sub-mm galaxies and Structure Formation - placing sub-mm galaxies in the Lambda-CDM framework
Cosmology Legacy Survey
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2. Sub-mm galaxies and Cosmic Star Formation History - constructing the evolving sub-mm luminosity function
Cosmology Legacy Survey
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3. Towards a detailed understanding of galaxy formation - testing semi-analytical, semi-numerical, and hydrodynamical models
Cosmology Legacy Survey
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Survey Status
Cosmology Legacy Survey
Survey approved in July 2005
490 hrs of band-1 time awarded to the 450 micron survey in semesters 09A,09B,010A,10B (=90% of all band-1 time)
630 hrs of band-2/3 time awarded to the 850 micron survey in semesters 09A,09B,10A,10B
SCUBA2 in Hawaii, awaiting final science grade arrays....