A SALT Spectropolarimetric Survey of Supernovae (“S 4 ”) K. Nordsieck Univ of Wisconsin

1. A SALT Spectropolarimetric Survey of Supernovae (“S4”)K. NordsieckUniv of Wisconsin • Supernova taxonomy • Polarization of Supernovae • Survey Structure • Why SALT? • Astrophysical questions • SNIa • Core Collapse SNe 1993J (IIb) SN Survey - SSII

2. Supernova Importance • Need to understand explosion process to model • return of heavy elements to ISM • energetic input to ISM • Need to clarify progenitors to couple to star formation/ galaxy models • Both I and II’s used for cosmological distance indicators- are they really standard candles? • Some really fun gas dynamics problems • Non spherical explosions a hot theoretical topic- needs observational input! • Possible relation to γ ray bursts SN Survey - SSII

3. Classification • Currently classified by 2 criteria • Spectra (I, II; a,b,c..) • Light Curves (P = plateau , L = linear) SN Survey - SSII

4. Past Polarization of Supernovae SN Survey - SSII

5. What Causes Polarization? • Two possibilities • Scattering of SN light off ambient dust – No, time dependence is wrong • Electron scattering in ejecta – Yes • Electron scattering pseudo-photosphere is asymmetric ~ 10 – 40%  0.5 – 2% pol • Explosion is homologous (Hubble flow). As it expands, see deeper into ejecta, to lower velocities and asymmetry of inner layers • Eventually, becomes optically thin, polarization vanishes • Line polarization • competition of line opacity with e-scat in photosphere  polarization reduction • P-Cygni lines above photosphere => polarization inverse P-Cygni SN Survey - SSII

6. Good Spectropolarimetry SN Survey - SSII

7. Survey • We need more than one example in each bin! • Adding asymmetry to spectra and light curve may clarify classification (eg Seyfert I-II unification) • Need • time coverage (3 -4 epochs) for classification and ISP estimation • to get on as early as possible (I highest pol, II unpol) • low resolution (R < 1000), very high S/N • can be done in poor seeing and bright/ grey moon SN Survey - SSII

8. Why SALT? • Spectroscopic survey distributed over sky – the best kind for SALT/ HET telescopes • Spectropolarimeter ~2x more sensitive than Keck LRS, VLT FORS1 • Polarimeter always available • 100% queue mode- can get on quickly, schedule epochs optimally SN Survey - SSII

9. Time estimation • Want to go down ~ 3 mag from peak • Use 900 l/mm VPH (R ~ 1000), binning to lower polarimetric resolution as required • => Faintest peak mag < 16 • Using discovery rate/yr for last 12 yrs, will see 10 – 20/year • Run for 3 years to get statistics • 20/ year x 4 epochs = 80 tracks = 8 nights = 3% of SALT • Soliciting SALT collaborators! SN Survey - SSII

10. Astrophysical questions - Ia • Ia’s claimed to be a one-parameter family: pk luminosity vs decline rate • Theoretical explanation: as time of deflagration  detonation gets earlier, get incomplete combustion, less Ni, lower lum, faster decline • But there must be a variety of progenitors, from accretion disk to WD mergers: how do these lead to one-parameter family • Clue from asymmetry: mergers should give more • The one low-lum Ia is more polarized than the one hi-lum one! SN Survey - SSII

11. Astrophysical Questions – Core Collapse • There are a variety of ways to induce asymmetry: • asymmetric explosion (axisymmetric? jet?) • ejecta running into asymmetrical environment (axisymmetric) • burning nonuniformities that make Ni clumps (non-axisymmetric) • Do II’s with different H envelope masses and environments all have the same asymmetry source? • Some are axisymmetric and some are not! SN Survey - SSII

12. SN 1993J (IIb) Tran et al 1997 PASP 109, 489 SN Survey - SSII

13. SN 2001el (Ia) Model Flux % Pol Ca jet axis Vector Continuum axis Kasen et al 2003 ApJ 593, 788 SN Survey - SSII

14. SN 1999em (II-P) Flux Spectral symmetry Time variability Leonard et al 2001 ApJ 553, 861 SN Survey - SSII