Finding the First Cosmic Explosions with JWST

1. Finding the First Cosmic Explosions with JWST Daniel Whalen McWilliams Fellow Carnegie Mellon University

2. My Collaborators • Chris Fryer (LANL) • Daniel Holz (LANL) • Massimo Stiavelli (STSci) • Alexander Heger (University of Minnesota) • Candace Joggerst (LANL) • Catherine Lovekin (LANL) • Lucy Frey (LANL)

3. Birthplaces of Primordial Stars ~ 200 pc 105 - 106 Msol halos at z ~ 20

4. Properties of the First Stars • thought to be very massive (25 - 500 solar masses) • due to inefficient H2 cooling • form in isolation (either one per halo or in binaries) • Tsurface ~ 100,000 K • extremely luminous sources of ionizing and LW photons • (> 1050 photons s-1) • 2 - 3 Myr lifetimes • no known mechanisms for mass loss -- no line-driven winds

5. Photoevaporation of a Halo by a Pop III Star Whalen, Abel & Norman 2004, ApJ, 610, 14

6. Primordial Ionization Front Instabilities Whalen & Norman 2008, ApJ, 675, 644

7. Final Fates of the First Stars Heger & Woosley 2002, ApJ 567, 532

8. Mixing & Fallback in 15 – 40 Msol Pop III SNe Joggerst, .., Whalen, et al 2010 ApJ 709, 11

9. Mixing in 150 – 250 Msol Pop III PI SNe Joggerst & Whalen 2011, ApJ, 728, 129

10. LANL Pop III Supernova Light Curve Effort Whalen et al. ApJ 2010a,b,c in prep • begin with 1D Pop III 15 – 40 Msol CC SN and 150 – 250 Msol • PI SN blast profiles • evolve these explosions through breakout from the surface of • the star out to 6 mo (CC SNe) or 3 yr (PI SNe) in the LANL • radiation hydro code RAGE (Radiation Adaptive Grid Eulerian) • post-process RAGE profiles with the LANL SPECTRUM code • to compute LCs and spectra • perform MC Monte Carlo models of strong GL of z ~ 20 SNe to • calculate flux boosts • convolve boosted spectra with models for absorption by the Lyman • alpha forest and JWST instrument response to determine • detection thresholds in redshift

11. Post Processing Includes Detailed LANL Opacities atomic levels are assumed to be in equilibrium: an approximation

12. Our Grid of Pop III SN Light Curve Models • 150, 175, 200, 225, and 250 Msol PI SN explosions, • blue and red progenitors, in modest winds and in • diffuse relic H II regions (18 models) • 15, 25, and 40 Msol CC SN explosions, red and blue • progenitors, three explosion energies in relic H II • regions only • red and blue progenitors span the range of expected • stellar structures for Pop III stars • core-collapse KEPLER blast profiles are evolved in 2D • in the CASTRO AMR code first up to shock breakout to • capture internal mixing—these profiles are then spherically • averaged and evolved in RAGE to compute LCs

13. u150 u175 u200 u225

14. PISN Shock Breakout • X-rays (< 1 keV) • transient (a few • hours in the local • frame)

15. Spectra at Breakout The spectra evolve rapidly as the front cools

16. Long-Term Light Curve Evolution

17. Late Time Spectra spectral features after breakout may enable us to distinguish between PISN and CC SNe

18. Conclusions • PISN will be visible to JWST out to z ~ 10 ; strong lensing may • enable their detection out to z ~ 15 (Holz, Whalen & Fryer 2010 • ApJ in prep) • dedicated ground-based followup with 30-meter class telescopes • for primordial SNe spectroscopy • discrimination between Pop III PISN and Pop III CC SNe will be • challenging but offers the first direct constraints on the Pop III IMF • complementary detection of Pop III PISN remnants by the SZ effect • may be possible (Whalen, Bhattacharya & Holz 2010, ApJ in prep)