A Bolometric Approach To Galaxy And AGN Evolution. L. L. CowieVenice 2006

(primarily from Wang, Cowie and Barger 2006, Cowie and Barger 2006 and Wang 2006 thesis)

The Hawaii bolometric sample: To understand the star formation and accretion history we need a census of all energy-producing galaxies & supermassive black holes in the universe, including those obscured by gas & dust.

Best to choose them by their bolometric light rather than at a single frequency.

The HDF /GOODS-N /CDF-N is still the best field for this!

Wide Hawaii HDF-N Data

BandSensitivity LimitTelescope / CameraSource(5sig Jy)U0.052KPNO 4mCapak et al. (2004)B0.063Subaru / SuprimeCamCapak et al. (2004)V0.069Subaru / SuprimeCamCapak et al. (2004)R0.083Subaru / SuprimeCamCapak et al. (2004)I0.209Subaru / SuprimeCamCapak et al. (2004)z0.251Subaru / SuprimeCamCapak et al. (2004)J0.839UH2.2m / ULBCAMTrouille et al. (2006) (400 sq arcmin)H1.06UH2.2m / ULBCAMTrouille et al. (2006)

3.6 m

0.327

Spitzer / IRAC

GOODS Spitzer Legacy Program4.5 m0.411Spitzer / IRACGOODS Spitzer Legacy Program5.8 m2.27Spitzer / IRACGOODS Spitzer Legacy Program8.0 m2.15Spitzer / IRACGOODS Spitzer Legacy Program24 m80Spitzer / MIPSGOODS Spitzer Legacy Program

Just under 4000 galaxies have been spectroscopically identified in the region: remainder can be assigned photometric redshifts. J and H data considerably improves the robustness at z>2.Spectroscopicredshifts (as ofearly 2006)

503 X-ray sources:(purple crosses) 202 20cm Radio sources (red squares): rectangle is core GOODS region.

HAWAII BOLOMETRIC SAMPLE:

2740 objects with 0.3-24 micron fluxes above 1.5x10^(-14) erg cm^(-2) s^(-1) in the 140 square arcminute core GOODS region.

This already contains all but 5 of the 40 microJy radio sources and all but 3 of the X-ray sources (CDF-N). We add the remaining 7 sources (2 are overlapped).

Goal is a near-complete spectrosopic identification of the sample: with a uniform 4000-10000A spectral database (DEIMOS spectrograph) of very high quality and spectral resolution.

Sample contains all of the 24 micron sources (this determines the limiting flux).

STATUS:

Goal is a complete spectrosopic identificationof the sample: currently 1890/2475 of the sources are spectroscopically identified and all but about 100 of these have high quality spectra.Red=X-ray AGN

Redshift distribution of Z band sources

Today I just want to focus on the analysis of the submillimeter light and its implications for the star formation

SCUBA Survey in the GOODS HDF-NGOODS HDF-N~110 arcmin2 by SCUBA0.4-4 mJy (rms) sensitivity~ 95 hours integration 27 sources at >3.5 Wang, Cowie, & Barger (2004)SCUBA 850m mapHST ACS imaging

Spectroscopy of 20cm Selected Submm SourcesChapman et al. (2005)18 Keck nights~ 100 submm sources observed~ 70 identifiedmedian redshift = 2.2

ProblemsSubmm sources that are above SCUBAs detection limit (~2 mJy) only contribute ~20% of the total submm background.Only 60% of the above 20% can be detected by radio telescopes to 40 microJy at 20cm.Chapmans radio selected submm sources only represent ~10% of the total background.

Need to know about the faint (

Cowie, Barger, Kneib 2002Typical source about 0.7mJy

Stacking Analysis

850 m Stacking Analysestotal 850 um EBL : 31-44 Jy deg-2 (COBE)

BandNI(mJy)(Jy Deg-2)ULB 1.6 m30940.20 0.0318.3 2.4IRAC 3.6 m52450.11 0.006619.6 3.4 MIPS 24 m4930.66 0.0611.4 1.1VLA 20 cm1011.31 0.134.0 0.401.6 m + 3.6 m178324.0 2.0

Submm EBL vs Spectral TypeIntrinsically Red Intrinsically Blue

Submm EBL vs Redshift

Compute star formation rates from measured 20cm fluxes of all the sources contributing to the submillimeter light (the core sample).

Compute average radio power of the sample in each redshift interval.

Assumes FIR-radio correlation but avoids assumptions about dust temperature.STAR FORMATION HISTORY:

Cosmic Star Formation History

Cosmic Star Formation History (txMdot)UVSubmm/20cm since Big BangMdot times tIntegrated star density

All of the backgrounds (including850 micron) have strong contributions from below z=1. However the UV and the 850 micron comefrom different galaxy populations.850UV[OII]850micron20 cm

SummaryWe detect most (60%-80%) of the submm EBL using the near-IR population.

Most of the submm EBL comes from intermediate type galaxies at z ~ 1. (Not the same sources that dominate the UV)Star formation history peaks at z ~ 1 and is flat at z > 1.

Wang, Cowie and Barger, 2006 astro-ph/512347 (ApJ upcoming)

The bolometric sample will appear shortly in Cowie and Barger (2006)

Number Counts from Clusters0.3-2 mJy : N(>S) = 3.5103 (S850/2 mJy)-1.2 deg-2 = 20 (+32/-8) Jy deg-2 Cowie, Barger, & Kneib (2002)

SuprimeCam0.450.45 Capak et al. (2004)HDF-proper

Spitzer ImagesGOODS Spitzer Legacy Program20 13Confusion limited at 3.6-4.5 m

Extragalactic Background Lighttotal 850 um EBL : 31-44 Jy deg-2

AGN in the Z band sample

Submm EBL vs Near-IR Color

B