infrared selection of obscured agn - 京都大学iwamuro/lecture/agn/ir_agn...infrared excess...

Infrared Selection of Obscured AGN

Astronomy 278

Outline

Motivation: Why search for AGN in the IR?

Infrared Selection techniques (Donley et al. 2008)

Compton Thick AGN

How can we get a complete selection of AGN?

Why select in the IR? IR Selection techniques Compton-Thick Completeness?

Other selection techniques (Radio, optical, X-ray) are known to be incomplete

What motivates the search for AGN at infrared wavelengths?

Want to be able to separately identify the non-stellar emission from a galaxy.

It is thought there is a population of AGN which are not being detected with any of the above techniques- the obscured or Compton-thick AGN.


AGN Spectrum in the MIR

Normal galaxy spectra


Infrared selection with Spitzer

GOODS-S

Herschel+Spitzer

The GOODS field is ideal for the characterization of IR selection techniques:

-Deep MIPS and IRAC -Overlap with deep X-ray and optical surveys


Donley et al. 2008 review three types of infrared selection:

Power law selection (Alonso-Herrero 2006, Donley 2007)

Color-Color Selection (Lacy et al. 2004, Stern et al. 2005)

IR-Excess Selection (Daddi et al. 2007)


IRAC power law selection

Select galaxies consistent with F α ν-0.5

Donley 2008 identify 55 power law galaxies (PLGs) in their sample of ~700 24-micron selected galaxies.

PLGs had a high fraction of X-ray counterparts: 45% ( 64% including marginal detections).

The detected & non-X-ray detected PLGs had consistent properties, suggesting they are all AGN.


Contamination

Power law selection appears to exclude most of the predicted contamination from star forming galaxies

Models of SED evolution for star forming galaxies


Color-Color selection--- The WedgesLacy et al. 2004Used models from ISO spectra to predict a color space dominated by AGN emission.

Lacy et al. 2007 tested this model for a sample of 24-micron selected galaxies, and find only 9% contamination.

Stern et al. 2005Empirically identify a Spitzer-IRAC color-space that isolates AGN, with estimated 80% completeness and less than 20% contamination

Lacy 2007

Stern 2005


Donley 2008 test both Stern & Lacy Wedges

Power-law selected galaxies fall almost entirely inside both wedges.

Donley et al. 2008


The Lacy 2004 color space includes essentially all sources at z > 1.75, irrespective of their nature

Potential for significant contamination from z ~2 star forming galaxies

Donley et al. 2008


20-30% of K-bright galaxies with 1.7 < z < 2.5 show a mid-infrared excess.

Daddi et al. 2007 analyze this population, and infer a hard X-ray spectrum from a stacking analysis.

They estimate that 50% of their sample are Compton-thick AGN.

Infrared Excess selection

Daddi et al. 2007

Donley et al. 2008 cannot rule this out, but suggest that the majority of these sources could be consistent with star formation alone.


What does it mean to be Compton thick?

NH > 1024 molecules per square centimeter

Sgr A*

Reflection-dominated spectra with wide Iron K α lines

Gilli 2007


Why do we think there is a large fraction of Compton-thick AGN?

Measurements of the column density in hard X-rays and soft gamma rays show that20-25% of the local AGN are Compton-thick.

Risaliti et al. 1999


Why care about Compton-thick AGN?

A significant population of Compton-thick AGN are required to fit the observed X-ray Background spectrum

Gilli et al. 2007

ComptonThick

Poor fit


Feruglio et al. 2011 find 2 Compton-thick AGN in the 4 Ms CDFS (z=2.5, 2.9). The implied volume density of Compton-thick sources is in agreement with predictions from XRB models.


Gilli et al. 2011 find a Compton-thick AGN in the 4 Ms CDFS at z=4.76, which was previously classified by optical spectroscopy.

Comastri et al. 2011 find 2 Compton-thick AGN in the CDFS with a 3.3 Ms XMM survey (z=1.53,3.70) that would have been missed by several IR-excess selection techniques. One of these sources is an analog to NGC 1068.


Color-color selection revisited (Donley et al. 2012)

Revise selection criteria to emphasize power-law selection, and a high x-ray detection fraction.

More efficiently exclude z~2 star forming galaxies

However, increase their bias toward detecting only the more luminous AGN

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4 Ms CDF observations of a sample of BzK selected galaxies.

Find that only 25% of these galaxies have X-ray spectra consistent with being Compton-thick.The rest are unobscured AGN and starbursts.

IR excess selection revisited (Alexander et al. 2011)

These results are inconsistent with fraction of Compton-thick AGN inferred from IR selection of Daddi and Fiore.


Currently, the most reliable way to identify Compton-thick AGN at high redshift appears to be with deep X-ray observations.

IR-selection techniques:

• Are biased against low-luminosity AGN and AGN with substantial host contribution

• Can suffer from contamination by star forming galaxies, especially at high redshift

• Can efficiently identify luminous, obscured AGN


Future prospects for detecting and characterizing Compton-thick AGN

Schleicher, Spaans & Klessen 2010

Just as the excitation of the ionized gas provides some of the most robust identification of AGN, the excitation of the molecular gas may also discriminate between the presence of an AGN and star formation.

infrared selection of obscured agn - 京都大学iwamuro/lecture/agn/ir_agn...infrared excess...

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