The µJy Sky and the Radio-FIR relation vs. z

1. The µJy Sky and the Radio-FIR relation vs. z EVLA Vision December 17, 2008

2. 1) µJy radio properties • Radio-FIR relation vs z 3) Implications, future directions Outline of Talk EVLA Vision December 17, 2008

3. G. Morrison (UH) • M. Pannella, V. Strazzullo, W-H. Wang (NRAO) • M. Polletta (Milan) • C. Lonsdale (NRAO) • A. Baker, Matt Klimek (Rutgers) • R. Ivison, A. Biggs (ROE) • D. Shupe (Herschel) • B. Wilkes (CFA) • R. Kilgard (Wesleyan) Short List of Collaborators EVLA Vision December 17, 2008

4. Deepest existing radio survey at 20cm (rms 2.7µJy), also 50cm (10µJy), 90cm (70µJy) • GALEX UV, ground-based optical, NIR, Spitzer IRAC, confusion-limited MIPS (24,70,160 µm),MAMBO 1.2mm, Chandra imaging, spectroscopy. • XMM, SCUBA2, Herschel HerMES 100-500µm (1st priority) to come. SWIRE Deep Field: 1046+59 EVLA Vision December 17, 2008

5. EVLA Vision December 17, 2008

6. Pannella/Strazzullo Radio Source Photo-z’s UgrizJHK3.6µ4.5µ EVLA Vision December 17, 2008

7. Radio Luminosities vs. z Majority of sources > 10^23 W/Hz, more luminous than Arp 220 EVLA Vision December 17, 2008

8. 1) µJysources are resolvedmedian size ~ 1 arcsecor ~10 kpc,unlike local ULIRGs < 100pc. EVLA Vision December 17, 2008

9. Median Sizes from 1046+59 Large median size for sources continues down to bottom of the survey. EVLA Vision December 17, 2008

10. Log N-log S continues flat to bottom of survey. 6 sources/sq arcmin. 20cm Log N –Log S Huyng et al 2005 EVLA: 10X deeper: natural confusion ? EVLA Vision December 17, 2008

11. Both ~ galaxy size, but different relation to optical light. Radio SF or AGN ? M84: AGN (Mechanical Energy) M82: SF EVLA Vision December 17, 2008

12. Relation of Radio and Optical Brightness distributions (GOODS-N) EVLA Vision December 17, 2008

13. Condon et al 2002 Radio SF vs. AGN Locally, AGN/SF luminosity functions cross at 10^23 W/Hz. <10^23 SF >10^23 AGN EVLA Vision December 17, 2008

14. Generic Radio/FIR Spectrum EVLA Vision December 17, 2008

15. For SF q=2.3 σ(q)~0.2 Radio-FIR Relation Condon et al 2002 EVLA Vision December 17, 2008

16. ULIRGs (Ultraluminous Infrared Galaxies) L_FIR > 10^12 L_sun Local examples have radio size < 100pc (LIRGs > 10^11 L_sun) Arp220 L_20cm=2.3x10^23 W/Hz L_FIR=1.2x10^12 L_sun EVLA Vision December 17, 2008

17. 24, 70 and 160 µm sources stacked at the radio source positions in ranges of L_20cm and z. • 160/70 µm ratio and error calculated. • Using redshifted templates with different dust temperatures, rest-frame: T(dust), L_FIR and q=log(L_20cm/L_FIR) are calculated. 24µ 70µ 160µ Radio-FIR Relation vs. z from Stacking Spitzer MIPS data EVLA Vision December 17, 2008

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24. Best fit opt/NIRSEDsStrazzullo et al(2009) EVLA Vision December 17, 2008

25. 5) X-rays EVLA Vision December 17, 2008

26. Star-formation and AGN activity go together: composites • Relation of AGN activity to evolutionary sequence still unclear but probably not related by a simple, one-time event. Too many star-forming galaxies with AGN evidence. • Deeper Herschel, XMM, EVLA data should make the picture clearer. • Deep EVLA imaging will probably be dominated by more extreme star-forming objects. May reach natural confusion. • Higher resolution radio observations from EVLA, eMerlin and SKA may be most productive path for more understanding. • Need new imaging algorithms for EVLA /eMerlin to make deep, wide-field images. Conclusions/Speculations EVLA Vision December 17, 2008