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A Model for GW Emission from CCSN Explosions. by Jeremiah W. Murphy NSF AAP Fellow (University of Washington). Collaborators: Christian Ott (Caltech), Adam Burrows (Princeton U.) . What is the mechanism of explosion?. Multi-Messenger Astrophysics: Exhibit A. Learn from GW?. Indirect. - PowerPoint PPT Presentation
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A Model for GW Emission from CCSN Explosions
byJeremiah W. Murphy
NSF AAP Fellow(University of Washington)
Collaborators:Christian Ott (Caltech), Adam Burrows (Princeton U.)
What is the mechanism of explosion?
Multi-Messenger Astrophysics: Exhibit A
Learn from GW?
IndirectDirect
Neutrino Mechanism:• Neutrino-heated convection• Standing Accretion Shock Instability (SASI)• Explosions? Maybe
Acoustic Mechanism:• Explosions but caveats.
Magnetic Jets:• Only for very rapid rotations• Collapsar?
Mechanism is inherentlymulti-dimensional
Mechanism is inherentlymulti-dimensional
GW Emission
Explosion Dynamics
Theory: to appreciate what we can learn from GWs
Fundamental Question of Core-Collapse Theory
?
Steady-StateAccretion
Explosion
Neutrino Mechanism:• Neutrino-heated convection• Standing Accretion Shock Instability (SASI)• Explosions? Maybe
Acoustic Mechanism:• Explosions but caveats.
Magnetic Jets:• Only for very rapid rotations• Collapsar?
M.
Le
Critical Curve
Steady-state accretion(Solution)
Explosions!(No Solution)
Burrows & Goshy ‘93Steady-state solution (ODE)
Is a critical luminosity relevant in hydrodynamic simulations?
How do the critical luminosities differ between 1D and 2D?
Murphy & Burrows ‘08
Murphy & Burrows ‘08
Nordhaus et al. ‘10
Why is critical luminosity of 2D simulations ~70% of 1D?
Turbulence
Solutions for successful explosions• Develop Turbulence model for CCSN• Use 3D simulations to calibrate • Derive critical curve with turbulence• Use turbulence model in 1D rad-hydro simulationsoQuick self consistent explosionsoSystematic investigations of explosions, NS masses, etc.
A Theoretical Framework
Murphy, Ott, and Burrows, ‘09
Initial LIGO
Enhanced LIGO
Advanced LIGO
Source Region for GWs?
Characteristic GW frequencies and amplitudes?
N2 < 0Convectively unstable
N2 > 0
N2 > 0Stably stratified(gravity waves)
b(r) = ∫ N2dr = buoyant accel.
N2 < 0Convectively unstable
N2 > 0
N2 > 0Stably stratified(gravity waves)
Dp Over shoot
The Model: Buoyant Impulse
vp
Dp ~ vp / N
fp ~ N/(2)
h+ fp vp
Similar analysis for 3D convection in stellar interiors(Meakin & Arnett 2007, Arnett & Meakin 2009)
The Model: Buoyant Impulse
Rb =b Dp
vp2
b(r) = ∫ N2dr
Dp ~ vp / N
fp ~ N/(2)
h+ fp vp
Similar analysis for 3D convection in stellar interiors(Meakin & Arnett 2007, Arnett & Meakin 2009)
Rb =b Dp
vp2
b(r) = ∫ N2dr
The Model: Buoyant Impulse
fp ~ N/(2)
Progenitor Mass and Luminosity Dependence
h+ fp vp
N2 = GMr
r3 Γ1
dlnPdlnr dlnr
dlnρ( )1 -
N2 = GMr
r3 Γ1
dlnPdlnr dlnr
dlnρ( )1 -
Dense matter EOS Local Thermodynamics andNeutrino transport
Summary
GW Emission•Explosion Mechanism•Protoneutron Star Structure•Dense Matter EOS•Explosion Dynamics
