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Supernova Sources of Gravitational Waves
� Instabilities�Proto-Neutron Star Instabilities
� Convection� Neutron Fingers
�Neutrino-Driven Convection� Rotation
�With and Without Magnetic Fields� Combination
Proto-Neutron Star Convection
Proto-Neutron Star Neutron Fingers
Neutrino-Driven Convection
Rotation sans Magnetic Fields
Rotation with Magnetic Fields
Previous Efforts
� Convection: � PNS: 100-1000 Hz� ND: 3-100 Hz� Energy Emitted 2-3 Orders of Magnitude Smaller in 3D PNS
�Janka and Mueller, Astron. Astrophys. 317, 140 (1997) � Rotation (Axisymmetry): 500-1000 Hz
�Zwerger and Mueller, Astron. Astrophys. 320, 209 (1997)� Asymmetric Collapse/Anisotropic Neutrino Emission: 10-500 Hz
�Burrows and Hayes, PRL 76, 352 (1996)� Rotation (Non-Axisymmetric):
� No considerable enhancement of gravitational radiation!
�Rampp, Mueller, and Ruffert, Astron. Astrophys. 332, 969 (1998).
Thorne, in Particle and Nuclear Astrophysicsand Cosmology in the Next Millenium, eds.E.W. Kolb and R. Peccei (World Scientific: Singapore), pg. 160 (1995).
EEssentially hydrodynamics studies.
Starting Point and Paradigm
Decrease with Anisotropy
Janka (2001)Janka and Mueller (1996)Burrows and Goshy (1993)
Liebendoerfer et al. (2001)Mezzacappa et al. (2001)Rampp and Janka (2000)
� Boltzmann transport results in significant quantitative changes in supernova models.� New nuclear physics and/or multi-D effects necessary ingredients in the explosion mechanism.
∂ρ∂ lnYl
s,P
∂ lnYl∂r
+∂ρ∂ ln s
Yl ,P
∂ ln s∂r
> 0
Ledoux Criterion sans Transport Effects:
Negative entropy and lepton fraction gradients are destabilizing.
Keil, Janka, and Mueller (1996)
Ray-By-Ray TransportGR
Mezzacappa et al. 1998
Spherically Symmetric TransportNewtonian
υ•
=gρ
αsθs
θ•
s = −θs
τ s
−dsdr
υ
θs = s − s
αs ≡ −∂ρ∂s
P,Yl
1τ
=1
τ BV2 +
14τ s
2
1/ 2
−1
2τ sτ s <<τ BV
→ τ s
τ BV
1τBV
υc, asymptotic τ s <<τ BV →
τ s
τ BV
υ c,asymptotic( )no transport
υ c,radial/ angular( )no transport ~ 108− 9cm / s
υ c,radial/ angular( )with transport
~ 106cm / s
Mezzacappa et al. 1998
Bruenn and Dineva (1996)
S
Y
High S, Low Y
Low S, High Y
Heat Flow
Lepton Flow
θ•
s = Σ sθs − ΣYlθYl
−dsdz
z•
θ•
Yl = Υsθs − ΥYlθYl
−dYl
dzz•
ρ z ••
= −g ∂ρ∂s
P ,Yl
θs − g ∂ρ∂Yl
P ,s
θYl
Aeα1t + Beα2t + Ceα3t
Aeα1t + Be (α2 + iβ) t + Ce (α2 −iβ ) t
αi = f (s,Yl ,αs ,αYl,Σ s ,ΥYl ,
dsdz, dY l
dz)
Equations governing motion of fluid element:
Solutions:
Wilson and Mayle (1993) - EoS DependentBruenn and Dineva (1996)
Bruenn and Dineva (1996)
Herant et al. (1994) Burrows, Hayes, and Fryxell (1995) Janka and Mueller (1996) Mezzacappa et al. (1998) Swesty (1998)
� Need fully 3D models.� Rotation will alter flow.
� Know very little about this interaction.� This is a radiation hydrodynamics problem.
� Transport powers explosion.� Convection depends on evolution of the gain region.
Newtonian Simulation GR Simulation
25 Solar Mass Model, 300 ms after Core Bounce
Shock ShockGain Radius Gain Radius
CoolingCooling
Heating
Heating
Neutrinos Neutrinos
MatterFlow
MatterFlow
Newtonian vs. GR Hydrodynamics
Supernova Sources of Gravitational Waves
� Instabilities�Proto-Neutron Star Instabilities
� Convection� Neutron Fingers
�Neutrino-Driven Convection� Rotation
�With and Without Magnetic Fields� Combination
Proto-Neutron Star Convection
Proto-Neutron Star Neutron Fingers
Neutrino-Driven Convection
Rotation sans Magnetic Fields
Rotation with Magnetic Fields
Previous Efforts
� Convection: � PNS: 100-1000 Hz� ND: 3-100 Hz� Energy Emitted 2-3 Orders of Magnitude Smaller in 3D PNS
�Janka and Mueller, Astron. Astrophys. 317, 140 (1997) � Rotation (Axisymmetry): 500-1000 Hz
�Zwerger and Mueller, Astron. Astrophys. 320, 209 (1997)� Asymmetric Collapse/Anisotropic Neutrino Emission: 10-500 Hz
�Burrows and Hayes, PRL 76, 352 (1996)� Rotation (Non-Axisymmetric):
� No considerable enhancement of gravitational radiation!
�Rampp, Mueller, and Ruffert, Astron. Astrophys. 332, 969 (1998).
Thorne, in Particle and Nuclear Astrophysicsand Cosmology in the Next Millenium, eds.E.W. Kolb and R. Peccei (World Scientific: Singapore), pg. 160 (1995).
EEssentially hydrodynamics studies.
Starting Point and Paradigm
Decrease with Anisotropy
Janka (2001)Janka and Mueller (1996)Burrows and Goshy (1993)
Liebendoerfer et al. (2001)Mezzacappa et al. (2001)Rampp and Janka (2000)
� Boltzmann transport results in significant quantitative changes in supernova models.� New nuclear physics and/or multi-D effects necessary ingredients in the explosion mechanism.
∂ρ∂ lnYl
s,P
∂ lnYl∂r
+∂ρ
∂ ln s
Yl ,P
∂ ln s∂r
> 0
Ledoux Criterion sans Transport Effects:
Negative entropy and lepton fraction gradients are destabilizing.
Keil, Janka, and Mueller (1996)
Ray-By-Ray TransportGR
Mezzacappa et al. 1998
Spherically Symmetric TransportNewtonian
υ•
=gρ
αsθs
θ•
s = −θs
τ s
−dsdr
υ
θs = s − s
αs ≡ −∂ρ∂s
P,Yl
1τ
=1
τ BV2 +
14τ s
2
1/ 2
−1
2τ sτ s <<τ BV
→ τ s
τ BV
1τBV
υc, asymptotic τ s <<τ BV →
τ s
τ BV
υ c,asymptotic( )no transport
υ c,radial/ angular( )no transport ~ 108− 9cm / s
υ c,radial/ angular( )with transport
~ 106cm / s
Mezzacappa et al. 1998
Bruenn and Dineva (1996)
S
Y
High S, Low Y
Low S, High Y
Heat Flow
Lepton Flow
θ•
s = Σ sθs − ΣYlθYl
−dsdz
z•
θ•
Yl = Υsθs − ΥYlθYl
−dYl
dzz•
ρ z ••
= −g ∂ρ∂s
P ,Yl
θs − g ∂ρ∂Yl
P ,s
θYl
Aeα1t + Beα2t + Ceα3t
Aeα1t + Be (α2 + iβ) t + Ce (α2 −iβ ) t
αi = f (s,Yl ,αs ,αYl,Σ s ,ΥYl ,
dsdz, dY l
dz)
Equations governing motion of fluid element:
Solutions:
Wilson and Mayle (1993) - EoS DependentBruenn and Dineva (1996)
Bruenn and Dineva (1996)
Herant et al. (1994) Burrows, Hayes, and Fryxell (1995) Janka and Mueller (1996) Mezzacappa et al. (1998) Swesty (1998)
� Need fully 3D models.� Rotation will alter flow.
� Know very little about this interaction.� This is a radiation hydrodynamics problem.
� Transport powers explosion.� Convection depends on evolution of the gain region.
Newtonian Simulation GR Simulation
25 Solar Mass Model, 300 ms after Core Bounce
Shock ShockGain Radius Gain Radius
CoolingCooling
Heating
Heating
Neutrinos Neutrinos
MatterFlow
MatterFlow
Newtonian vs. GR Hydrodynamics
� Neutrino-driven models with convection and rotation.Fryer and Heger (2000)
� MHD-driven models with rotation and magnetic fields.LeBlanc and Wilson (1979)Symbalisty (1984)Khokhlov, Hoeflich, Oran, Wheeler, Wang, and Chtchelkanova (1999)
� Paradigm shift?� Multiple mechanisms?
� “Collapsar” models driven by neutrinos, MHD effects, or both.
MacFadyen and Woosley (1999)
� Multiple mechanisms?
Precollapse models are improving.
Nonrotating ModelsUmeda, Nomoto, and Nakamura (2000)Heger, Woosley, Martinez-Pinedo, and Langanke (2000)
Rotating ModelsHeger, Langer, and Woosley (2000)
Chemical DiffusionConvectionSemiconvection
Rotation-Induced InstabilitiesShear InstabilitiesSolberg-Høiland InstabilityEddington-Sweet CirculationGoldreich-Schubert-Fricke Instability
“The distribution of angular momentum in the star at onset of core collapse strongly reflectsits recent convective structure.” - Heger, Langer, and Woosley 2000
Mechanisms for angular momentumtransport.
Magnetic fields ignored.
Initial fields?Field-Instability Interactions
Transport angular momentum.Buoyancy
Thomas Fermi (Classical)
Hartree-Fock
Shell Model DiagonalizationShell Model Monte Carlo
Bloch-Horowitz
Advanced solutions to the many body problem.
Solve “exact” many-body problem.
Time
Classical treatment of many-bodyproblem.
Lowest order solution to the quantum mechanical many-body problem.
ν-nucleus
High-Density EoS
Ensembles
β-decay
e-capture
Nuclear MatterOpacities
Densityof States
�Inner core mass proportional to square of mean electron fraction.�~10% change in inner core mass dynamically significant.
Langanke and Martinez-Pinedo,NPA 673, 481 (2000)
Past Approximations:Degeneracy and Relativity Composition (allowed degrees of freedom)Baryon-Baryon Interactions
Reddy, Prakash, and Lattimer, PRD, 58, 13009 (1998)
Interacting matter of arbitrary degeneracy and relativity.Accounted for in-medium mass and energy shiftsat Hartree-Fock level.
Multiple-component matter (e.g., hyperons).Additional interaction channels.
Reddy, Prakash, Lattimer, and Pons, PRC, 59, 2888 (1999)
Correlations.Accounted for interactions at the RPA level.
Burrows and Sawyer, PRC 58, 554 (1998)Burrows and Sawyer, PRC 59, 510 (1999)
Raffelt and Seckel (1995)Janka et al. (1996)Hannestadt and Raffelt (1999)
Challenges and Requirements
� Requires an interdisciplinary team effort: astrophysicists, nuclear physicists, applied mathematicians, computer scientists.
� Scalable algorithms for radiation hydrodynamics (MHD, MRHD).� Scalable algorithms for the solution of large, sparse linear systems/large eigenvalue problems.
� Parallel programming issues.� Software engineering issues.� Collaborative visualization.
� Develop a standard model of core collapse supernovae.� 3D.� Accurate multigroup neutrino transport.� Realistic nuclear and weak interaction physics.� GR.� MHD.
http://www.phy.ornl.gov/tsi/
Goal: Develop a Standard Model of Core Collapse Supernovae
� Successful model for the explosion mechanism(s)� Reproduce supernova phenomenology
Neutrino, Gravitational Wave, Gamma Ray Signatures
� Neutron star kicks� Gamma ray burst association
Nu
cleo
syn
thes
is
Investigator Team
Radiation Transport/Radiation Hydrodynamics
� Blondin (NC State)� Bruenn (FAU)� Hayes (UCSD)� Mezzacappa (ORNL)� Swesty (SUNYSB)
Nuclear Structure Computationsfor EOS and Neutrino-Nucleus/Nucleon Interactions
� Dean (ORNL, UT)� Fuller (UCSD)� Haxton (INT, Washington)� Lattimer (SUNYSB)� Prakash (SUNYSB)� Strayer (ORNL, UT)
Linear System/Eigenvalue Problem SolutionAlgorithms for Radiation Transport andNuclear Structure Computation
� Dongarra (UT, ORNL)� Saied (UIUC, NCSA)� Saylor (UIUC, NCSA)
Visualization
� Baker (NCSA)� Toedte (ORNL)
�Cross-Cutting Team�Long-Term Collaborations�Structured like SciDAC
Supernova Science
� Blondin� Bruenn� Fuller� Haxton� Hayes� Lattimer� Meyer (Clemson)� Mezzacappa� Swesty
TOPS
TOPS
DATA
CCAPERCTSTT
Start Year 1 Year 2
3D Ray-by-Ray (MGBT)Newtonian
2D Ray-by-Ray (MGBT)Newtonian
2D MGFLDNewtonian
2D Ray-by-Ray (MGBT)Approximate GR
3D MGFLDNewtonian
Year 3
2D MGBTNewtonian
2D MGFLDApproximate GR
3D Ray-by-Ray (MGBT)Approximate GR
Supernova Simulation TimelineSupernova Simulation Timeline
GW signatures from convection, rotation.
86: B fields.
Summary
� Gravitational Waves from Proto-Neutron Star Instabilities (Convection, Neutron Fingers)
Requirements for Reliable Waveforms: 3D Radiation Hydrodynamics (Neutrino-Matter Interactions Important)
� Gravitational Waves from Postshock 3D Flow (Neutrino-Driven Convection, Shock Induced Vorticity and Turbulence)
Requirements: 3D Radiation Hydrodynamics (Neutrino Flux Determines “Boundary Conditions”)
� Gravitational Waves from Rotation/Combination of Rotation and ConvectionRequirements: 3D Precollapse Models
3D Supernova Models
� Gravitational Waves with B Fields Requirements: 3D MRHD
TSI is committed to a concerted effort to compute reliable waveforms in all of the above cases, with first results available within the next few years for GWsfrom instabilities. (GWs from rotation will remain uncertain.)