1. IFU studies of GRBs and SNe regions Lise Christensen (Excellence Cluster Universe, Technical University Munich) + Maryam Modjaz (NY), + Christina Thoene (IAA, Granada), + Susanna Vergani (INAF, Brera) + Aybuke Yoldas (IOA, Cambridge)

2. What makes a GRB? Fireball model

3. GRBs/SNe connection Hjorth et al. 2003 Bloom et al. 1999 SN bump Type Ic

4. Core collapse explosion types Type II : + H Type Ib : - H + He Type Ic : - H - He - Si binary mass transfer? Type Ic broad lined (hypernova): - H – He E kin >10 52 erg (model dependent) line widths: ~30 000 km/s no GRB GRB / Ic –bl : metal poor : < 10% solar, fast rotating GRB/ no SN Ic –bl ( SN detections are the exception – Fynbo+ 2006) Yoon et al. 2006

5. What makes a GRB/ hypernova? – We never spotted a progenitor of a Type Ib/c SN Clues from their hosts: Progenitor star mass Stellar population age Metallicity proximity to HII regions Host galaxy studies

6. HST images of hosts of long duration bursts at z=1 (Fruchter et al 2006)

7. Redshift/host magnitude distribution Jakobsson et al. 2010

8. Host of GRB 980425 - SN 1998 bw (z=0.0085) FORS BVRVIMOS cube Compare IFU- with archive data: Magnitudes and colours have to match broad band data Extracted narrow band IFU image has to match Ha narrow band images IFU extracted spectra have to match long slit spectra 30” = 5 kpc HST WFPC

9. GRB 980425 host: Derived properties Christensen et al 2008 Ha emission line fit - > velocity map -> dynamic mass Ha flux -> SFR, Specific SFR <- 24  m Spitzer image Ha flux / continuum -> Ha EW -> age Ha/Hb -> reddening E(B-V) Flux ratios [OIII]/Hb / [NII]/Ha   Oxygen abundance Each spectrum > stellar population fitting -> stellar mass,age GRB region is not so unusual 12+log(O/H)

10. GRB 060505 (z=0.08) VIMOS cubeFORS - R Thoene et al. 2010 GRB site: No SN detected young: 6 Myrs = 32 M  star metal poorer than the galaxy (slit spectra)  progenitor likely a massive star

11. Unusual emission line ratios? Models: Dopita et al. 2006 980425 051117B E(B-V)=0.5, solar metallicity

12. Metallicities In GRB/SNe regions Modjaz et al. 2008

13. GRB – SN connections Modjaz et al. 2010 But disagrees with Anderson et al. 2010 Kelly et al 2008 Metallicity distribution SN/GRB location in host

14. NGC 6754: 4 SNe in 10 years NICMOS,F110W, FOV~50” Type Ia Type II Type Ia N

16. Old: 30-40% level detector fringes New: ~10% IFU fringes in some spectra (also present In old data) New VIMOS detectors

17. New VIMOS detector sensitivities Q1 Q2 Q3 Q4 old new

18. Future studies of SNe hosts Type Ic / Ic –bl (without GRBs) Targeted / non-targeted galaxies Sample of ~ 20 galaxies (Current status: applied for observations) M B = -21 to -18

19. Ongoing studies of GRB hosts VLT 2010 - IFU programmes: Low-z hosts with Sinfoni + AO : High spatial resolution on four closest hosts Stellar population in the GRB site ~100 pc (Z, age, mass) (PI: A. Yoldas) High-z : Sinfoni – No AO: locate galaxies in line of sight (Mg II absorbers) faint emission from GRB hosts (PI: S. Vergani) GRB 021004 (z=2.33) [O III] 5007

20. Summary Aim: to distinguish GRB and SN regions from host studies Systematic differences in metallicity between GRB and SNe Unusual regions in hosts – maybe for GRBs, but unknown for SNe Ic’s Only looked systematically at HII region emission lines (GRB/SNe) Underlying stellar populations to be investigated (GRB/SNe) Upgrade of VIMOS detectors is promising for future studies

22. z=0.08 shortish duration: 4s no SN detected in lightcurve at very deep limits (nor with spectroscopy) Located in large star-forming region GRB 060505 - questioning the GRB-SN connection

23. Higher spectral resolution Flames- ARGUS archive data R~10000 Courtesy: M. Dessauges-Zavadsky + F. Hammer

24. Modjaz et al. 2010 Global metallicity in SN hosts