1. Statistical Properties of Radio Galaxies in the local Universe Yen-Ting Lin Princeton University Pontificia Universidad Católica de Chile Yue Shen, Michael Strauss, Ragnhild Lunnan (Princeton), Zheng Zheng (IAS)

2. outline motivations science goals –consensus of radio galaxies (RGs) hosted by massive galaxies in the local universe (z  0.3) –formation mechanism of RGs –identification of interesting objects for detailed study the sample several statistics to look at –relationship with radio-quiet (RQ) population –dependence on the environment

3. motivation: to make the bright end of the luminosity function right Croton et al (2006)

4. motivation: SZ surveys are happening! credit: CXO Carlstrom et al (2002) Atacama Cosmology Telescope in construction see Lin et al (0805.1750) for estimation of effects of radio sources on SZ signal

5. using NYU-VAGC DR6 LSS galaxy sample as parent sample, containing ~220,000 galaxies down to M r  –20.5 (about M * ) cross-matched with NVSS and FIRST surveys at 1.4 GHz to generate the largest radio galaxy catalog to date: 10,500 RGs stronger than 3mJy improvements over previous studies –construction of several volume-limited subsamples –90% of RGs have measured redshift –all RGs visually inspected to secure matches and measurement of fluxes –morphology information of radio sources –high S/N measurement of correlation functions –halo occupation distribution (HOD) modeling the sample

6. bivariate luminosity function whole sample M  -20.5 volume-limited M  -21.5 volume-limited

7. bivariate luminosity function

8. optical luminosity function 0.02  z  0.132 108,873 galaxies 2,253 RGs 2.1% of galaxies more luminous than M * have radio power logP  23.12 fiber collision correction applied

9. correlation function both galaxies and RGs are volume-limited and subject to same optical luminosity cut (M r  –21.5) RGs (red) more strongly clustered than galaxies (blue) clustering length comparable to groups of galaxies (~10h -1 Mpc)

10. correlation function: HOD modeling consider N RG =N RG,cen +N RG,sat N RG,cen =1 if(M  M min ) N RG,sat =(M/M 1 )  HOD modeling suggests RGs are hosted by halos more massive than 10 13 M sun (consistent with lensing results from Mandelbaum et al 2008)

11. RGs in massive halos: halo occupation number count galaxies and RGs at M r  – 20.5 in 134 X-ray clusters from ROSAT all-sky survey number of galaxies goes as M 0.8 occupation number of RGs not a strong function of cluster mass 1435 galaxies, 85 RGs (~6%) 62/134 (=46%) clusters host RGs among these, 34 have RL BCGs 44 clusters host only 1 RG, 20 of these are BCG 25% of BCGs are RL 3.9% of non-BCG galaxies are RL NOTE: 2.1% of galaxies are RL globally BCGs clusters w/o RGs

12. RGs in massive halos: spatial distribution

13. RGs in dense regions excess number of neighbors –1000 RGs, 1000 RQ galaxies matched to optical luminosity, apparent magnitude, and redshift –count nearby objects out to 2 Mpc from SDSS photometric catalog, within –23.5  M r  –20.5 –within ~0.5 Mpc, RL galaxies always have higher number of neighbors than RQ ones Mpc

14. RGs in dense regions no RLAGN–SF galaxy pairs at scales<1Mpc! caution: small number of SF galaxies in the sample!

15. summary observations: –given optical luminosity and color, RGs are more strongly clustered than the corresponding RQ galaxy sample –large scale clustering implies hosts are group or cluster-sized halos –RGs very centrally concentrated towards halo center ingredients for RL AGN phenomenon –dense environment –presence of intracluster/intragroup gas: confining pressure –low level supply of gas: what’s the source? work in progress –dissection of the bivariate LF –environment of high and low-excitation RL AGNs (e.g., FRI vs FRII) –relationship with X-ray and optical AGNs