Dust emission from powerful high-z starbursts and QSOs
The combined power of submillimeter and mid-IR studies for tracing the most powerful starbursts of massive galaxies at high redshift, and their AGN.
Alain Omont (IAP)
Substantial and most spectacular star formation at z > 1
The hidden part of the evolution of most massive galaxies and black-holes
Multi- interplay between submm at APEX with Spitzer, Herschel and IR-optical
OUTLINE
Background:
High z submillimeter galaxies (SMGs)
Millimeter dust detection in high z SMGs and QSOs
Prospects with APEX: high speed wide fields; multi-Laboca-1 (+SZ-camera): Spitzer (+ IRAM) eraNext generation cameras: SCUBA2, Herschel eraALMA era
Dust emission from powerful high-z QSOs and starbursts
OUTLINE
Background:
High z submillimeter galaxies (SMGs)
Millimeter dust detection in high z SMGs and QSOs
MAMBO & SCUBA maps
Prospects with APEX: high speed wide fields; multi-Laboca-1 (+SZ-camera): Spitzer (+ IRAM) eraNext generation cameras: SCUBA2, Herschel eraALMA era
Dust emission from powerful high-z QSOs and starbursts
z Dphot (Gpc)
1000
--------------------
20 230
12 130
--------------------
z= 6 60
--------------------
z=2 16 -------------------
0.5 3--------------------
0
~ 300 million
~ 3.5 billion
z ~ 7 – 20 ?- Reionization PopIII stars +1st galaxies-Formation of 1st galaxies Pop. II stars - First AGN
z ~ 4 – 7 :Current frontier- Galaxy and Black-Hole early assembly- End of reionization
z ~ 1.5 -4: - Peak of star formationsubmm sources + LBGs-Peak of QSO activity -Luminous mid-IR sour. -Proto-cluster formation
z ~ 0.5-1.5 : Final phase of active SF - Mid-IR sources- Weak X-ray AGN- Cluster formation
Main z ranges in the Cosmic History of galaxies
SMGs: strongest starbursts in the Universe
Giant starbursts at the peak of elliptical formation z ~ 2-3 1-4
At least Ultra-Luminous Infra-Red Galaxies (ULIRGs):
• LFIR >~ 1012 Lo, SFR > 100 Mo/yr
• Relatively rare, but up to ~1 per arcmin2
• Generally not isolated; strongly biased along high-z Large Scale Structures
• Probably progenitors of massive elliptical galaxies
• A few of these objects are powerful QSOs or radiogalaxies MBH >~ 108 Mo
from Bertoldi, Voss, WalterLfir = 4x1012 S250(mJy) Lsun
FIR emission of cold dust (Td ~ 35-50 K) :
- steep submm spectrum - compensates for distance - S practically independent of z from z ~ 0.5 to 10
Effect also known as « negative K correction »
Redshift degeneracy
Dust detection: The Magic of the high-z submm window
SCUBA (+MAMBO) submm counts SCUBA(-radio) redshift distributionChapman, Blain, Ivison, Smail 2003
SCUBA(-MAMBO) census of high-z ULIRGs
• Take advantage of steep submm spectrum• Account for most of submm background• z at Keck for radio ones (~50%) (weak AGN ?) History of star formation up to z~3-4• Small but uncertain number at z > 4
Dust detection: the magic of the submm window
1. MAMBO detection of high-z QSOs
+ A. Beelen, F. Bertoldi, C. Carilli, P. Cox et al.
2. MAMBO detection of high-z Spitzer SMGs
+ C. Lonsdale, SWIRE team + European-IRAM team
3. Examples of MAMBO mapsF. Bertoldi, Voss, C. De Breuck
MAMBO 1.2mm detection of far-IR/submm dust emission in high z SMGs and QSOs
MAMBO/IRAM detection of redshifted far-IR/submm dust (+ CO) emission from high-z QSOs
Aims
• To establish correlations between major starbursts and black-holes at high z
(in the context of the black-hole/spheroid relation (MBH-, MBH/Msph)
• It is the easiest way to find (biased) cases of ULIRGs at very high z, since the redshifts of SCUBA/MAMBOsources are practically unknown at z > 4
• It is thus better to search similar sources around known objects: (bright) QSOs
with z~2-6
Observations
IRAM 30m Telescope (Granada, Spain)
+ MAMBO bolometer cameras
built at MPIfR Bonn (E. Kreysa)
MAMBO/IRAM detection of redshifted far-IR/submm dust (and CO) emission from high-z QSOs
Summary of results
(probably very similar to bright Scuba SMGs)
• High rate of detection : ~55 sources detected ~ 25%
• No significant dependence of the far-IR luminosity on z
• The mm/submm emission is dominated by cold dust at 40-50 K
• LFIR ~ 1013 Lo HLIRGs SFR ~ 1000 Mo/yr ?
• Heating of cold dust by starburst or AGN, or both ? Both are viable; probably a combination of both in various proportions, but some starburst is probably always present in the sources detected at 1.2 mm (CO detections in some sources)
• The far-IR luminosity is weakly correlated with rest UV Lbol
Identification and follow-up of SMGs in SWIRE/Spitzer
Spitzer/SWIRE should have detected~several 103s SMGs (in 50 deg2)
MAMBO project (30h observed, 30h programmed Winter 2006)
Broad European + SWIRE collaboration, Lonsdale, Omont et al.
Selection from Spitzer SEDs of ULIRGs (e.g. Arp220) z
First results (27 sources observed):3 sources ~ 5 mJy
13 sources ~ 2-3 mJy (2- 3) : LFIR ~ 1013 Lo SFR ~ 1000 Mo/yr 9 sources « 1-1.5 » (~1-1.5 mJy)
Proposal spectroscopy IRS Spitzer
Identification and follow-up of SMGs in SWIRE/Spitzer
Spitzer/SWIRE should have detected~several 103s SMGs (in 50 deg2)
MAMBO project (30h observed, 30h programmed Winter 2006)
Broad European + SWIRE collaboration, Lonsdale, Omont et al.
Selection from Spitzer SEDs of ULIRGs (e.g. Arp220) z
First results (27 sources observed):3 sources ~ 5 mJy
13 sources ~ 2-3 mJy (2- 3) : LFIR ~ 1013 Lo SFR ~ 1000 Mo/yr 9 sources « 1-1.5 » (~1-1.5 mJy)
Proposal spectroscopy IRS Spitzer
Example of MAMBO mapVoss et al. 2005
LABOCA-1
300 detectors, 870m, 12m
Faster for mapping than MAMBO (117, 1.2mm, 30m)
Much faster than SCUBA-1
Wide fields:
Matching surveys at other wavelengths:
Spitzer (GOODS, GTO, SWIRE, etc.), HST, CFHTLS, UKIDSS, VST, VIRCAM/CFHT, X, radio
Peaks of density : - SZ clusters, - Proto-clusters, filaments, around tracers such as radio
galaxies, QSOs, etc.
Exceptional objects: z > 5, HLIRGs, lenses, (pre-)clustering
Next generation cameras
• 350 mm : importance of multi- data
• TES detectors : mandatory to sustain SCUBA-2 competition for wide deep surveys matching Herschel (+ Spitzer, Astro-F, Spica? …)
+ SZ Camera : data at 2 mm
Summary/Conclusion
The mm/submm range is essential to study the major starbursts of the assembly of the most massive galaxies and their relation with the growth of their super-massive black-hole
Such most extreme objects have no equivalent locally, but they are major actors in the evolution of the Universe at z ~2-3
A very large sample of high-z SMGs/AGN already exists in Spitzer data
Surveys with APEX (and later with SCUBA2, Herschel etc.) are needed to identify large number of them, their spatial clustering and highest z and most exceptional ones
Multi-capability is essential
Extensive studies with ALMA
Conclusion
The mm/submm range is essential to study the major starbursts of the assembly of the most massive galaxies and their relation with the growth of their super-massive black-hole
Such most extreme objects have no equivalent locally, but they are major actors in the evolution of the Universe at z ~2-3
One needs larger samples of HLIRGs to explore the bright end of the SMG luminosity function, their properties and evolution
New multi- surveys, such as CFHTLS and SWIRE, provide powerful and unique tools to identify high-z starbursts and AGN, possibly dusty, such as Type 2 QSOs and HLIRGs
This field will strongly develop in the near future in particular with Herschel, the new generation of submm cameras and especially ALMA
IRAM should remain the best millimeter facility for almost a decade before ALMA and the next generation of single dishes such as LMT (but GBT & EVLA)
Power of Spitzer for mid-IR detection of various classes of AGN, especiallyhigh z Type 2 QSOs
SED (L) often relatively flat in the whole infrared
J1148 QSO at =6.4
Landmarks and questions of the evolution of most massive galaxiesand associated super-massive black-holes
Final mass 1011 – 1012 Moz ~ 4 - 10Major starbursts in the 1st billion yr at DM density peaks (first LSSs) LBGs & Ly Galaxies SMGs: ULIRGs & HLIRGs ?
1.5 ~< z <~ 3 Peak of starburst SMGs• SCUBA/MAMBO counts• Mergers & pre-clustering ? • CO detection• Detection in Spitzer wide surveys+ Distant Red Galaxies ?
z < 1-1.5 Decline of SMGs mostly passive evolution (+stellar mergers) massive elliptical galaxies + supermassive cD cluster galaxies
Final black-hole mass 108 – 109 Mo
First SMBHs MBH ~ 109 Mo A few most powerful QSOs z=6.4 Fewer Radio Galaxies z >~4
Major phase of SMBH growth Peak of QSO activity• Weak AGN activity in most SMGs• X-absorbed QSOs and Type 2 QSOs• Spitzer IR QSOs ? SMBH mergers ?
Very few powerful QSOsDormant most massive SMBHsbut strong feedback in clusters?
QSO Feedback
Spheroid/Black-Hole Relation
All spheroids contain a super-massive black-hole (MBH ~ 106-109 Mo) with
MBH ~ 4-5
= velocity dispersion in the spheroid (elliptical, bulge …)
MBH ~ 2 10-3 Msph
Consistent with black-hole growth from AGN luminosity
Might be explained by feedback from AGN expelling gas in the spheroid and stopping black-hole growth, more easily in smaller dark-matter halos