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Star Formation Rate and Neutral Gas Content as a Function of Redshift and Environment Collaborators: Mike Pracy, Jayaram Chengalur, Frank Briggs, Matthew.

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Presentation on theme: "Star Formation Rate and Neutral Gas Content as a Function of Redshift and Environment Collaborators: Mike Pracy, Jayaram Chengalur, Frank Briggs, Matthew."— Presentation transcript:

1 Star Formation Rate and Neutral Gas Content as a Function of Redshift and Environment Collaborators: Mike Pracy, Jayaram Chengalur, Frank Briggs, Matthew Colless Galaxy Metabolism: Galaxy Evolution Near and Far 2009 Philip Lah

2 The Star Formation Rate Density of the Universe

3 Star Formation Rate Density Evolution Compilation by Hopkins 2004

4 Galaxy HI mass vs Star Formation Rate

5 Galaxy HI Mass vs Star Formation Rate HIPASS & IRAS data z ~ 0 Doyle & Drinkwater 2006

6 The HI Gas Density of the Universe

7 HI Gas Density Evolution Not a log scale

8 HI Gas Density Evolution Zwaan et al. 2005 HIPASS HI 21cm Rao et al. 2006 DLAs from MgII absorption Prochaska et al. 2005 & 2009 DLAs Lah et al. 2007 coadded HI 21cm

9 The Fujita galaxies H  emission galaxies at z = 0.24

10 The Fujita Galaxies Subaru Field 24’ × 30’ narrow band imaging  Hα emission at z = 0.24 (Fujita et al. 2003, ApJL, 586, L115) 348 Fujita galaxies 121 redshifts using AAT GMRT ~48 hours on field DEC RA

11 Star Formation Rate Density Evolution Compilation by Hopkins 2004

12 Star Formation Rate Density Evolution Compilation by Hopkins 2004 Fujita et al. 2003 value

13 Coadded HI Spectrum

14 HI spectrum all Fujita galaxies coadded HI spectrum using 121 redshifts - weighted average raw

15 HI spectrum all Fujita galaxies coadded HI spectrum using 121 redshifts - weighted average raw binned M HI = (2.26 ± 0.90) ×10 9 M 

16 The HI Gas Density of the Universe

17 HI Gas Density Evolution Lah et al. 2007 coadded HI 21cm

18 Galaxy HI mass vs Star Formation Rate

19 Galaxy HI Mass vs Star Formation Rate HIPASS & IRAS data z ~ 0 Doyle & Drinkwater 2006

20 HI Mass vs Star Formation Rate at z = 0.24 line from Doyle & Drinkwater 2006 all 121 galaxies

21 HI Mass vs Star Formation Rate at z = 0.24 line from Doyle & Drinkwater 2006 42 bright L(Hα) galaxies 42 medium L(Hα) galaxies 37 faint L(Hα) galaxies

22 Abell 370 a galaxy cluster at z = 0.37

23 Abell 370, a galaxy cluster at z = 0.37 large galaxy cluster of order same size as Coma  similar cluster velocity dispersion and X-ray gas temperature optical imaging ANU 40 inch telescope spectroscopic follow-up with the AAT GMRT ~34 hours on cluster HI z = 0.35 to 0.39 Abell 370 cluster core, ESO VLT image

24 Abell 370 galaxy cluster 324 galaxies 105 blue (B-V  0.57) 219 red (B-V > 0.57) Abell 370 galaxy cluster

25 HI Mass Measurements

26 HI mass 324 galaxies 219 galaxies 105 galaxies 94 galaxies 168 galaxies 156 galaxies 110 galaxies 214 galaxies

27 HI mass 324 galaxies 219 galaxies 105 galaxies 94 galaxies 168 galaxies 156 galaxies 110 galaxies 214 galaxies

28 HI mass 324 galaxies 219 galaxies 105 galaxies 94 galaxies 168 galaxies 156 galaxies 110 galaxies 214 galaxies

29 HI mass 324 galaxies 219 galaxies 105 galaxies 94 galaxies 168 galaxies 156 galaxies 110 galaxies 214 galaxies

30 HI mass 324 galaxies 219 galaxies 105 galaxies 94 galaxies 168 galaxies 156 galaxies 110 galaxies 214 galaxies

31 Galaxy HI mass vs Star Formation Rate

32 Galaxy HI Mass vs Star Formation Rate HIPASS & IRAS data z ~ 0 Doyle & Drinkwater 2006

33 HI Mass vs Star Formation Rate in Abell 370 all 168 [OII] emission galaxies line from Doyle & Drinkwater 2006 Average

34 HI Mass vs Star Formation Rate in Abell 370 81 blue [OII] emission galaxies line from Doyle & Drinkwater 2006 87 red [OII] emission galaxies Average

35 Why is there a dramatic evolution in the Cosmic Star Formation Rate Density and only minimal evolution in the Cosmic HI Gas Density?

36 Evolution of HI Gas in Galaxies log(SFR)  log(M HI ) SFR = a (M HI ) m  HI =  M HI SFRD =  SFR SFRD = a ×  (M HI ) m m ~ 1.7 at z = 0 (Doyle & Drinkwater 2006) Vol

37 Evolution of HI Gas in Galaxies log(SFR)  log(M HI ) SFR = a (M HI ) m  HI =  M HI SFRD =  SFR SFRD = a ×  (M HI ) m m ~ 1.7 at z = 0 (Doyle & Drinkwater 2006) Vol

38 Evolution of HI Gas in Galaxies log(SFR)  log(M HI ) SFR = a (M HI ) m  HI =  M HI SFRD =  SFR SFRD = a ×  (M HI ) m m ~ 1.7 at z = 0 (Doyle & Drinkwater 2006) Vol

39 Evolution of HI Gas in Galaxies log(SFR)  log(M HI ) SFR = a (M HI ) m  HI =  M HI SFRD =  SFR SFRD = a ×  (M HI ) m m ~ 1.7 at z = 0 (Doyle & Drinkwater 2006) Vol

40 Evolution of HI Gas in Galaxies log(SFR)  log(M HI ) SFR = a (M HI ) m  HI =  M HI SFRD =  SFR SFRD = a ×  (M HI ) m m ~ 1.7 at z = 0 (Doyle & Drinkwater 2006) Vol

41 Downsizing the stellar populations of the most massive galaxies formed at early times (Heavens et al. 2004, Thomas et al. 2005 & others) the sites of active star formation shift from the high-mass galaxies at earliest times to the lower-mass galaxies at later periods (Cowie et al. 1996, Gunzman et al. 1997 & others) high-mass galaxies with active star formation  highest HI gas content?

42 Downsizing the stellar populations of the most massive galaxies formed at early times (Heavens et al. 2004, Thomas et al. 2005 & others) the sites of active star formation shift from the high-mass galaxies at earliest times to the lower-mass galaxies at later periods (Cowie et al. 1996, Gunzman et al. 1997 & others) high-mass galaxies with active star formation  highest HI gas content?

43 Downsizing the stellar populations of the most massive galaxies formed at early times (Heavens et al. 2004, Thomas et al. 2005 & others) the sites of active star formation shift from the high-mass galaxies at earliest times to the lower-mass galaxies at later periods (Cowie et al. 1996, Gunzman et al. 1997 & others) high-mass galaxies with active star formation  highest HI gas content?

44 Future Observations - HI coadding with SKA Pathfinders

45 SKA pathfinders large field of view ASKAP 30 deg 2 (focal plane array) MeerKAT 1.2 to 4.8 deg 2 (1420 to 700 MHz) frequency coverage out 700 MHz  HI redshift z = 1.0 optical redshift surveys ASKAP use WiggleZ MeerKAT use zCOSMOS and others

46 Conclusion

47 used coadded HI 21-cm emission to measure the cosmic HI gas density at z = 0.24; value is consistent with that from damped Lyα measurements; shown SFR–M HI relationship holds at z = 0.24 galaxies around Abell 370 at z = 0.37 have significantly amounts of gas; shows clear environmental trends similar to nearby systems; shown SFR–M HI relationship holds at z = 0.37 to explain difference in evolution between SFR and HI gas postulated either a varying SFR–M HI relationship or a varying HI mass function Conclusion

48 used coadded HI 21-cm emission to measure the cosmic HI gas density at z = 0.24; value is consistent with that from damped Lyα measurements; shown SFR–M HI relationship holds at z = 0.24 galaxies around Abell 370 at z = 0.37 have significantly amounts of gas; shows clear environmental trends similar to nearby systems; shown SFR–M HI relationship holds at z = 0.37 to explain difference in evolution between SFR and HI gas postulated either a varying SFR–M HI relationship or a varying HI mass function Conclusion

49 used coadded HI 21-cm emission to measure the cosmic HI gas density at z = 0.24; value is consistent with that from damped Lyα measurements; shown SFR–M HI relationship holds at z = 0.24 galaxies around Abell 370 at z = 0.37 have significantly amounts of gas; shows clear environmental trends similar to nearby systems; shown SFR–M HI relationship holds at z = 0.37 to explain difference in evolution between SFR and HI gas postulated either a varying SFR–M HI relationship or a varying HI mass function Conclusion

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