Presentation is loading. Please wait.

Presentation is loading. Please wait.

Keck Observations of Two Supernovae Hours After Explosion Shock-Breakout Flash Spectroscopy as a New Window into the Evolution and Death of Massive Stars.

Published byJuniper Cooper Modified over 5 years ago

Similar presentations

Presentation on theme: "Keck Observations of Two Supernovae Hours After Explosion Shock-Breakout Flash Spectroscopy as a New Window into the Evolution and Death of Massive Stars."— Presentation transcript:

1 Keck Observations of Two Supernovae Hours After Explosion Shock-Breakout Flash Spectroscopy as a New Window into the Evolution and Death of Massive Stars Daniel Perley (Caltech) O. Yaron (Weizmann) A. Gal-Yam (Weizmann) E. Ofek (Weizmann) iPTF team

2 Palomar Transient Factory

3 Palomar Transient Factory

4 PTF → iPTF PTF ( ): Various strategies, but typically 3-day cadence. Find large numbers of transients. Intermediate PTF (2013-present): Various strategies, but typically 1-hour cadence. (3 visits per night, every night) Find new types of fast-varying transients, and find “ordinary” supernovae very early.

5 iPTF Nightly Scanning Scanners Palomar Keck

6 iPTF 13ast UGC 7610 (D = 108 Mpc) 2013 May 3 04:14 UT
SDSS reference image (Gal-Yam+2014, Nature 509:471)

7 Keck Observations DEIMOS spectrum @ 0.64 days Fλ
LRIS 6.45 days Wavelength (A) DEIMOS trigger and spectum

8 Keck Observations DEIMOS spectrum @ 0.64 days Fλ
DEIMOS 0.64 days N III HeII C IV, He I N IV LRIS 6.45 days Wavelength (A) DEIMOS trigger and spectum

9 Keck Observations DEIMOS spectrum @ 0.64 days
DEIMOS 0.64 days N III HeII C IV, He I N IV LRIS 6.45 days DEIMOS trigger and spectum

10 Shock Breakout Below a Stellar Wind
star X UV opt (spectrum just above stellar surface)

11 Shock Breakout Below a Stellar Wind
star shock X UV opt (spectrum just above stellar surface)

12 Shock Breakout Below a Stellar Wind
X UV opt (spectrum just above stellar surface)

13 Shock Breakout Below a Stellar Wind
X UV opt (spectrum just above stellar surface)

14 Shock Breakout Below a Stellar Wind
ionized wind X UV opt X UV opt (spectrum just above stellar surface)

15 Shock Breakout Below a Stellar Wind
ionized wind X UV opt (spectrum just above stellar surface)

16 Shock Breakout Below a Stellar Wind
X UV opt (spectrum just above stellar surface)

17 Shock Breakout Below a Stellar Wind
X UV opt (spectrum just above stellar surface)

18 Flash Spectroscopy: Progenitor Diagnostic
Flash-excited spectrum resembles a Wolf-Rayet star of type WN(h) (No oxygen: CNO-processed material is exposed in wind) IIb progenitor is a WR? Perhaps not (Groh 2014), but evolutionary link probably exists

19 Pre-Explosion Behavior
Hα luminosity constrains mass-loss rate (for inner wind; probes material emitted in last ~10 years pre-explosion) ~ M☉/yr Extremely rapid mass loss! Cannot be steady-state and very unlikely to be coincidental: star was highly unstable just before explosion (onset of C burning...?)

20 iPTF 13dqy 2013 October 8 NGC 7610 (D = 51 Mpc)
SDSS reference image (Yaron, Perley et al in prep.)

21 Early Keck Observations
0.26 d r-band light curve Swift UVW2 light curve Wavelength (A) LRIS trigger and spectra time (days)

22 Early Keck Observations
0.26 d O IV O VI He II O V r-band light curve Swift UVW2 light curve Wavelength (A) LRIS trigger and spectra time (days)

23 13dqy Spectra 0.26 d 0.30 d 0.37 d 0.42 d 0.88 d 1.4d 2.0d 5.3d 8.8d 10.9d 20.2d 22.4d 27.1d 31.3d 43.3d

24 13dqy Spectra 0.26 d 0.30 d Flash-excited narrow lines 0.37 d 0.42 d
Hot continuum II-P supernova

25 Line Profiles O IV, O V: No narrow core,
Continuum-subtracted spectrum O IV, O V: No narrow core, Broad component only (all material is inner; t >> 1) but, O VI has a weak narrow component? H I, He II: Narrow core (recombination of outer material) + Broad wings (Thomson scattering of inner material)

26 Line Flux Evolution Hydrogen peaks at ~1.5 d; disappears between 6-8 d
He II peaks at ~1.0 d, disappears between 2-5 d O V, O VI peak at <0.3 d and disappear by 2 d

27 Flash-Ionization and Light Travel Time
106 breakout Unflashed wind EUV-flashed wind EUV flash: ~ hour 105 EUV flash NUV flash cooling to Keck NUV flash: ~day 104 NUV-flashed wind pre-explosion time 8 light-days (=1360 AU, =2.1 × cm) surface temperature (K)

28 13dqy Preliminary Results
Shock-breakout flash: Flash temperature ~105 K, lasting ~1 hour Mass-loss history: Emitting region ~ few light days Recent mass-loss rate ~10- 4 M☉/yr (Again not steady-state – late instability?) Slow wind velocity (< 100 km/s) Red supergiant progenitor, exploding during a period of greatly enhanced mass loss. Wind/surface composition: H/O-rich. (Possibly N-poor?)

29 Stellar Wind Flash Tomography

30 The Future This is only the beginning!
Every core-collapse SN may very well behave this way. 2 out of 2 with <1 day observations Search of PTF archive finds several more transient H/He signatures in early (~few days) spectra. Early SN Ia spectra taken so far do not show these features. ~1 SN at <100 Mpc per day A few <1 day detections per year with iPTF A few <1 day detections per month with ZTF HIRES monitoring of a SN over first few days would provide detailed tomography of the spatially resolved wind Approved HST UV spectroscopy proposal starting next year (PI Gal-Yam)

31 Summary iPTF 13ast (II-b): H, He, N lines disappearing in <5 days
Progenitor was oxygen-depleted Enhanced mass loss / ejection in final years iPTF 13dqy (II-P): H, He, O lines disappearing in 1-5 days Progenitor wind oxygen-rich RSG progenitor, with enhanced mass loss All cc-SNe may show flash-excited early spectra, and All cc-SNe may undergo enhanced mass loss shortly before exploding.

32

33 Three Supernova Spectra

34 Three Supernova Spectra
N IV He II C IV N IV He I very hot SN IIn Wavelength (A) featureless hot continuum featureless hot continuum Fe II H Ca II SN IIb He I He I

35 Three Supernova Spectra
N IV He II C IV N IV He I very hot SN IIn featureless hot continuum featureless hot continuum Fe II Wavelength (A) H Ca II SN IIb He I He I

36 Three Supernova Spectra
N IV He II C IV N IV He I very hot SN IIn featureless hot continuum featureless hot continuum Fe II H Ca II SN IIb He I He I

37 Three Supernova Spectra
t = 0.64 days N IV He II C IV N IV He I very hot SN IIn t = 3.1 days featureless hot continuum featureless hot continuum t = 69 days Fe II H Ca II SN IIb He I He I

Download ppt "Keck Observations of Two Supernovae Hours After Explosion Shock-Breakout Flash Spectroscopy as a New Window into the Evolution and Death of Massive Stars."

Similar presentations

Pair-Instability Explosions: observational evidence Avishay Gal-Yam, Weizmann Institute Nikko 2012.

Pair-Instability Explosions: observational evidence Avishay Gal-Yam, Weizmann Institute Nikko 2012.
Insights from Radio Wavelengths into Supernova Progenitors Laura Chomiuk Jansky Fellow, Michigan State University.

Insights from Radio Wavelengths into Supernova Progenitors Laura Chomiuk Jansky Fellow, Michigan State University.
SN 1987A spectacular physics Bruno Leibundgut ESO.

SN 1987A spectacular physics Bruno Leibundgut ESO.
Stellar Evolution. Evolution on the Main Sequence Zero-Age Main Sequence (ZAMS) MS evolution Development of an isothermal core: dT/dr = (3/4ac) (  r/T.

Stellar Evolution. Evolution on the Main Sequence Zero-Age Main Sequence (ZAMS) MS evolution Development of an isothermal core: dT/dr = (3/4ac) (  r/T.
The Flavours of SN II Light Curves Iair (“ya-eer”) Arcavi Advisor: Avishay Gal-Yam.

The Flavours of SN II Light Curves Iair (“ya-eer”) Arcavi Advisor: Avishay Gal-Yam.
Stellar Evolution: The Deaths of Stars Chapter Twenty-Two.

Stellar Evolution: The Deaths of Stars Chapter Twenty-Two.
The Deaths of Stars Chapter 13. The End of a Star’s Life When all the nuclear fuel in a star is used up, gravity will win over pressure and the star will.

The Deaths of Stars Chapter 13. The End of a Star’s Life When all the nuclear fuel in a star is used up, gravity will win over pressure and the star will.
SN 2012fr in NGC 1365 Mark M. Phillips, Carlos Contreras, Eric Hsiao, Nidia Morrell, Kevin Krisciunas, Peter Brown, and Max Stritzinger.

SN 2012fr in NGC 1365 Mark M. Phillips, Carlos Contreras, Eric Hsiao, Nidia Morrell, Kevin Krisciunas, Peter Brown, and Max Stritzinger.
The evolution and collapse of BH forming stars Chris Fryer (LANL/UA)  Formation scenarios – If we form them, they will form BHs.  Stellar evolution:

The evolution and collapse of BH forming stars Chris Fryer (LANL/UA)  Formation scenarios – If we form them, they will form BHs.  Stellar evolution:
From Progenitor to Afterlife Roger Chevalier SN 1987AHST/SINS.

From Progenitor to Afterlife Roger Chevalier SN 1987AHST/SINS.
What can we learn on the BLR from the smallest AGN? Or, how do the BLR properties change with luminosity, and what is it telling us? Specifically The BLR.

What can we learn on the BLR from the smallest AGN? Or, how do the BLR properties change with luminosity, and what is it telling us? Specifically The BLR.
The Independency of Stellar Mass-Loss Rates on Stellar X-ray Luminosity and Activity Space Telescope Science Institute – 2012.

The Independency of Stellar Mass-Loss Rates on Stellar X-ray Luminosity and Activity Space Telescope Science Institute – 2012.
Finding the First Cosmic Explosions with JWST and WFIRST Daniel Whalen McWilliams Fellow Carnegie Mellon University.

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

Finding the First Cosmic Explosions Daniel Whalen McWilliams Fellow Carnegie Mellon University.
Low-luminosity GRBs and Relativistic shock breakouts Ehud Nakar Tel Aviv University Omer Bromberg Tsvi Piran Re’em Sari 2nd EUL Workshop on Gamma-Ray Bursts.

Low-luminosity GRBs and Relativistic shock breakouts Ehud Nakar Tel Aviv University Omer Bromberg Tsvi Piran Re’em Sari 2nd EUL Workshop on Gamma-Ray Bursts.
Supernovae from Massive Stars: light curves and spectral evolution Bruno Leibundgut ESO.

Supernovae from Massive Stars: light curves and spectral evolution Bruno Leibundgut ESO.
SN 1987A the excitement continues Bruno Leibundgut ESO.

SN 1987A the excitement continues Bruno Leibundgut ESO.
COOL STARS and ATOMIC PHYSICS Andrea Dupree Harvard-Smithsonian CfA 7 Aug. 2006 High Accuracy Atomic Physics In Astronomy.

COOL STARS and ATOMIC PHYSICS Andrea Dupree Harvard-Smithsonian CfA 7 Aug High Accuracy Atomic Physics In Astronomy.
NASA's Chandra Sees Brightest Supernova Ever N. Smith et al. 2007, astro-ph/0612617v2.

NASA's Chandra Sees Brightest Supernova Ever N. Smith et al. 2007, astro-ph/ v2.
Hot Gas in Planetary Nebulae You-Hua Chu Robert A. Gruendl Martín A. Guerrero Univ. of Illinois.

Hot Gas in Planetary Nebulae You-Hua Chu Robert A. Gruendl Martín A. Guerrero Univ. of Illinois.

Similar presentations

Ads by Google