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On the enhancement of the Ly equivalent width by a multiphase interstellar medium or: debunking the Neufeld scenario Peter Laursen With Florent Duval & Gran stlin (OKC) Dark Cosmology Centre | Niels Bohr Institutet | Kbenhavns

  1. On the enhancement of the Ly α equivalent width by a multiphase interstellar medium – or: debunking the Neufeld scenario Peter Laursen With Florent Duval & Göran Östlin (OKC) Dark Cosmology Centre | Niels Bohr Institutet | Københavns Universitet www.dark-cosmology.dk/~pela

  2. Motivation Lyman α emitting galaxies (LAEs) are important probes of the high-redshift Universe: • Epoch of Reionization • Baryonic Acoustic Oscillations • Luminosity function (faint end) These are statistical properties. Individual observations are hampered by insufficient knowledge about radiative transfer effects. One way, however, to probe individual galaxies is by looking at the equivalent width of Lyα. 2

  3. Motivation Equivalent width: “Max 240 Å!”, say Charlot & Fall (1993), and Schaerer (2003). “But… but…”, say Kudritzki et al. (2000), Malhotra & Rhoads Boost: (2002), Rhoads et al. (2003), Dawson et al. (2004), Hu et al. (2004), Shimasaku et al. (2006), Ouchi et al. (2008), Nilsson et al. (2009), Kashikawa et al. (2011), etc. “Clumpiness!”, say Chapman et al. (2005), Finkelstein et al. (2007, 2008, 2009a,b,c, 2011a,b), Dayal et al. (2008, 2009, 2010, 2011), Niino et al. (2009), Yuma et al. (2010), Kobayashi et al. (2010), Blanc et al. (2011), Nakajima et al. (2012), etc. 3

  4. Lyman α radiative transfer H I 4

  5. Lyman α escape Gas density and temperature Dust density and cross-section Neufeld (1990) T = 10 4 K, N HI = 10 19 cm -2 , E ( B – V ) = 0.1 5

  6. Multiphase medium Neufeld (1991); Hansen & Oh (2006) 6

  7. Neufeld 1991 7 Enter Hansen & Oh (2006)

  8. Systematic approach M O C A L A TA (Laursen et al. 2009) 8

  9. Varying the input parameters “Fiducial” model: 3 • Covering factor, f c 1 cm -3 • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) Z  0 km s -1 • Cloud velocity dispersion, σ V,cl 0 km s -1 • Galactic outflow velocity, V out 0 cm -3 • Intercloud HI density, n HI,ICM 0 • Intercloud dust density (  Z ICM ) Central • Emission scale length, H 0 • Emission/cloud correlation factor, P cl 0 • Intrinsic line width, σ line 10 4 K; 10 6 K • Gas temperature, T cl ; T ICM 100 pc • Cloud size distribution, r cl,min ; r cl,max ; β 9

  10. Varying the input parameters (on at a time) • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 10

  11. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 11

  12. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 12

  13. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 13

  14. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 14

  15. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 15

  16. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 16

  17. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 17

  18. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 18

  19. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 19

  20. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 20

  21. Varying the input parameters • Covering factor, f c • Cloud HI density, n HI,cl • Cloud dust density (  metallicity, Z cl ) • Cloud velocity dispersion, σ V,cl • Galactic outflow velocity, V out • Intercloud HI density, n HI,ICM • Intercloud dust density (  Z ICM ) • Emission scale length, H • Emission/cloud correlation factor, P cl • Intrinsic line width, σ line • Gas temperature, T cl ; T ICM • Cloud size distribution, r cl,min ; r cl,max ; β 21

  22. From ideal to semi-realistic (varying in unison) 22

  23. From ideal to semi-realistic (each dot is the result of a model) 23

  24. From ideal to semi-realistic 24

  25. From ideal to semi-realistic 25

  26. From ideal to semi-realistic 26

  27. Line profiles Average spectrum of boost-yielding (extreme) models — not realistic (too narrow) 27

  28. Alternative scenarios • Top-heavy IMF (Malhotra & Rhoads 02) • Population III stars (Schaerer 03, Tumlinson 03) • Delayed escape of Lyα (Roy+ 10, Xu+ 11) • AGN activity (<5%, Wang+ 04, Gawiser+ 06) • Viewing angle (Laursen 07/09, Verhamme 12) • Cooling radiation (Dijkstra+ 09, Laursen+ 09, Dayal+ 10) • Measuring errors (Henry+ 10) • Star formation stochasticity (Forero-Romero & Dijkstra 12) • Inhomogeneous escape (Hayes+ 07) 28

  29. Alternative scenarios • Top-heavy IMF (Malhotra & Rhoads 02) • Population III stars (Schaerer 03, Tumlinson 03) • Delayed escape of Lyα (Roy+ 10, Xu+ 11) • AGN activity (<5%, Wang+ 04, Gawiser+ 06) • Viewing angle (Laursen 07/09, Verhamme 12) • Cooling radiation (Dijkstra+ 09, Laursen+ 09, Dayal+ 10) • Measuring errors (Henry+ 10) • Star formation stochasticity (Forero-Romero & Dijkstra 12) • Inhomogeneous escape (Hayes+ 07) 29

  30. Viewing angle (even in a homogeneous medium, without dust, a “boost” can be measured) 30

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