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Single versus Binary Star Progenitors of Type IIb Supernovae

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Presentation on theme: "Single versus Binary Star Progenitors of Type IIb Supernovae"— Presentation transcript:

1 Single versus Binary Star Progenitors of Type IIb Supernovae
SN 1987A, 30 years later Feb 20, 2017 Niharika Sravan, Pablo Marchant, & Vicky Kalogera

2 Stripped Envelope Supernovae (SNe)
H He SUPERNOVA Type II Core REMOVE OUTER LAYERS H IIb He Core SE SNe SUPERNOVA Ib Core Core He Ic

3 THE PROGENITOR CONNECTTION
What mechanism(s) drive the stripping of stripped-envelope SNe is an open question Answer is connected to what their progenitors are MECHANISMS DOMINATING STRIPPING Single Star Progenitors Stellar Winds Binary Star Progenitors Close Binary Interactions Which mechanism = which progenitor

4 Progenitor Observations
Luminosity (L☉) Teff (K) Focus: Type IIb Sne Progenitor Observations Luminosity log10(L/L☉) = 4.72 – 5.4 Effective Temperature log10(Teff/K) = 3.58 – 3.8 Light Curves Hydrogen envelope mass 0.01 – 0.5 M☉ Helium core mass 2 – 6 M☉ Abundant ~ 10-12% a,b,c of all core-collapse SNe 30-40% a,b,c of all SE SNe Six with detected progenitors Only stripped envelope SN progenitor with detected binary companion a Shivvers et al., 2016 b Li et al., 2011 c Smith et al., 2011 Type IIb

5 Single vs binary star Progenitors of
ZAMS Single Binary Core-collapse Progenitor Hydrogen Envelope Mass Helium Core Mass Luminosity Effective Temperature Models Observation Evolve Observed Progenitor Properties Hydrogen Envelope Mass 0.01 – 0.5 M☉ Helium Core Mass 2 – 6 M☉ Luminosity log10(L/L☉) = 4.72 – 5.4 Effective Temperature log10(Teff/K) = 3.58 – 3.8 Single vs binary star Progenitors of type IIb Sne (METHOD) Type IIb

6 MODEL parameter SPACE *solar metallicity, non-rotating
Parameter search space Single star models*: M/M☉ = 10 – 80 Binary star models*: M1/M☉= 10 – 18 M2/M☉= 6 – M1 log10(Porb /d) = 0.0 – 4.0 Conservative and non-conservative MT the question – thus shed light on role of and characteristic of physics the method *solar metallicity, non-rotating Type IIb

7 NO Can single stars be type IIb Sn progenitors?
Helium core mass Models Models with residual Hydrogen envelope mass 0.01 – 0.5 M☉ (candidates) Observations Sravan et al., in prep Models NO Observations Luminosity and Teff Type IIb

8 Can binary stars be type IIb Sn progenitors?
Parameter space occupied by binary star models reaching core-collapse with 0.01 – 0.5 M☉ residual Hydrogen envelope (candidates) Sravan et al., in prep

9 YES! Can binary stars be type IIb Sn progenitors?
Helium core mass Observations Models with residual Hydrogen envelope mass 0.01 – 0.5 M☉ (candidates) Models Sravan et al., in prep Observations YES! Models Luminosity and Teff Type IIb

10 Summary We find solar-metallicity, non-rotating single stars cannot be Type IIb progenitors ** Solar-metallicity, non-rotating binary stars can be Type IIb progenitors ** These systems have: Mass ratios > 0.6 3.2 < log10(Porb,i) < 3.6 Companion luminosity: 4 < log10(L/L☉)< 4.8 Predicted rate ~ 1% of all CC SNe Rates too low

11 Future Work Complete parameter space:
binary star models Mprim > 20M☉ Study light curves from IIb progenitor models Rates too low

12 Thank you!

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