Literature Catalog: Gravitational Waves from Core Collapse Supernovae
maintained by
Ewald Müller, MaxPlanckInstitut für Astrophysik, Garching, Germany

Last updated on April 5, 2022

2022
Finkel, B. and Andresen, H. and Mandic, V.
Stochastic gravitationalwave background from stellar corecollapse
events
Phys. Rev. D105, 063022 (2022)
Gill, K. and Hosseinzadeh, G. and Berger, E. and Zanolin, M. and
Szczepanczyk, M.
Constraining the time of gravitationalwave emission from
corecollapse supernovae
eprint arXiv:2201.03609 (2022)
Jardine, R. and Powell, J. and Müller, B.
Gravitational wave signals from 2D corecollapse
supernova models with rotation and magnetic fields
MNRAS 510, 5535 (2022)
Kuroda, T. and Fischer, T. and Takiwaki, T. and Kotake, K.
Corecollapse supernova simulations and the formation of neutron
stars, hybrid stars, and black holes
ApJ 924, 38 (2022)
Nakamura, K. and Takiwaki, T and Kotake, K.
Threedimensional simulation of a corecollapse supernova for a
binary star progenitro of SN1987A
eprint arXiv:2202.06295 (2022)
Powell, J. and Müller, B.
Inferring astrophysical parameters of corecollapse supernovae
from their gravitationalwave signal
Phys. Rev. D 105, 063018 (2022)
Raynaud, R. and CerdaDuran, P. and Guilet, J.
Gravitational wave signature of protoneutron star convection:
I. MHD numerical simulations
MNRAS 509, 3410 (2022)
Raza, N. and McIver, J. and Dalya, G. and Raffai, P.
Prospects for reconstructing the gravitationalwave signals from
corecollapse supernovae with Advanced LIGOVirgo and the
BayesWave algorithm
eprint arXiv:2202.08960 (2022)
Vartanyan, D. and Coleman M.S.B. and Burrows, A.
The collapse and threedimensional explosion of threedimensional
massivestar supernova progenitor models
MNRAS 510, 4689 (2022)
2021
Andresen, H. and Glas, R. and Janka, H.Th.
Gravitationalwave signals from 3D supernova simulations with
different neutrinotransport methods
MNRAS 503, 3552 (2021)
Afle, C. and Brown, D.A.
Inferring physical properties of stellar collapse by
thirdgeneration gravitationalwave detectors
Phys. Rev. D103.023005 (2021)
Bizouard, M.A. and MaturanaRussel, P. and TorresForne, A. and
Obergaulinger, M. and CerdaDuran, P. and Christensen, N. and
Font, J.A. and Meyer, R.
Inference of protoneutron star properties from gravitationalwave
data in corecollapse supernovae
Phys. Rev. D103.063006 (2021)
Chan, M.L. and Hayama, K.
Estimate of the detectability of the circular polarization signature
of supernova gravitational waves using the Stokes parameters
Phys. Rev. D103.103024 (2021)
Coleman M.S.B. and Burrows, A. and White, C.J.
The physical effect of progenitror rotation: comparing two
longduration 3D corecollapse supernova simulations
eprint arXiv:2111.00022 (2021)
Edwards, M.C.
Classifying the equation of state from rotating core collapse
gravitational waves with deep learning
Phys. Rev. D103.024025 (2021)
Eggenberger Andersen, O. and Zha, S. and da Silva Schneider, A. and
Betranhandy, A. and Couch, S.M. and O'Connor, E.P.
Equation of state dependence of gravitational waves in
corecollapse supernovae"
ApJ 923, 201 (2021)
Halim, O. and Casentini, C. and Drago, M. and Fafone, V. and
Scholberg, K. and Vigorito, C.F. and Pagliaroli, G.
Multimessenger analysis strategy for corecollapse supernova
search: gravitational waves and lowenergy neutrinos
JCAP 11, 021 (2021)
LIGO Scientific Collaboration; Virgo collaboration
Allsky search for short gravitationalwave bursts in the third
Advanced LIGO and Advanced Virgo run
Phys. Rev. D104, 122004 (2021)
Lopez, M. and Di Palma, I. and Drago, M. and CerdaDuran, P. and
Ricci, F.
Deep learning for corecollapse supernova detection
Phys. Rev. D103.063011 (2021)
Mukherjee, S. and Nurbek, G. and Valdez, O.
Study of efficient methods of detection and reconstruction of
gravitational waves from nonrotating 3D general relativistic core
collapse supernovae explosion using multilayer signal estimation
method
Phys. Rev. D103.103008 (2021)
Pajkos, M.A. and Warren, M.L. and Couch, S.M. and O'Connor, E.P. and
Pan, K.C.
Determining the structure of rotating massive stellar cores with
gravitational waves
ApJ 914, 80 (2021)
Pan, K.C. and Liebendörfer, M. and Couch, S.M. and Thielemann, F.K.
Stellar mass black hole formation and multimessenger signals from
threedimensional rotating corecollapse supernova simulations
ApJ 914, 140 (2021)
Powell, J. and Müller, B. and Heger, A.
The final core collapse of pulsational pair instability supernovae
MNRAS 503, 2108 (2021)
Richardson, C. and Zanolin, M. and Andresen, H. and
SzczepaÅ„czyk, M. J. and Gill, K. and Wongwathanarat, A.
Modeling corecollapse supernovae gravitationalwave memory
in laser interferometric data
eprint arXiv:2109.01582 (2021)
Shibagaki, S. and Kuroda, T. and Kotake, K. and Takiwaki, T.
Characteristic time variability of gravitationalwave and neutrino
signals from threedimensional simulations of nonrotating and
rapidly rotating stellar core collapse
MNRAS 502, 3066 (2021)
Sotani, H. and Takiwaki, T. and Togashi, H.
Universal relation for supernova gravitational waves
Phys. Rev. D104,123009 (2021)
Szczepanczyk, M. and Antelis, J. and Benjamin, M. and Cavaglia, M. and
GondekRosinska, D. and Hansen, T. and Klimenko, S. and Morales, M.
and Moreno, C. and Mukherjee, S. and Nurbek, G. and Powell, J. and
Singh, N. and Sitmukhambetov, S. and Szewczyk, P. and Valdez, O.
and Vedovato, G. and Westhouse, J. and Zanolin, M. and Zhen, Y.
Detecting and reconstructing gravitational waves from the next
galactic corecollapse supernova in the advanced detector era
Phys. Rev. D104.102002 (2021)
Takeda, M. and Hiranuma, Y. and Kanda, N. and Kotake, K. and
Kuroda, T. and Negishi, R. and Oohara, K. and Sakai, K. and
Sakai, Y. and Sawada, T. and Takahashi, H. and Tsuchida, S. and
Watanabe, Y. and Yokozawa, T.
Application of the HilbertHuang transform for analyzing
standingaccretionshockinstability induced gravitational
waves in a corecollapse supernova
Phys. Rev. D104.084063 (2021)
Takiwaki, T and Kotake, K. and Foglizzo, T.
Insights into nonaxisymmetric instabilities in threedimensional
rotating supernova models with neutrino and gravitationalwave
signatures
MNRAS 508, 966 (2021)
Wei, Y.F. and Liu, T. and Xue L.
Anisotropic neutrinos and gravitational waves from black hole
neutrinodominated accretion flows in fallback
corecollapse supernovae
MNRAS 507, 431 (2021)
2020
Chan, M.L. and Heng, I.S. and Messenger, C.
Detection and classification of supernova gravitational wave
signals: A deep learning approach
Phys. Rev. D102.043022 (2020)
LIGO Scientific Collaboration; Virgo Collaboration
An Optically Targeted Search for Gravitational Waves emitted by
CoreCollapse Supernovae during the First and Second Observing Runs
of Advanced LIGO and Advanced Virgo
Phys. Rev. D101, 084002 (2020)
Mezzacappa, A. and Marronetti, P. and Landfield, R.E. and Lentz, E.J. and
Yakunin, K.N. and Bruenn, S.W. and Hix, W.R. and Messer, O.E.B. and
Endeve, E. and Blondin, J.M. and Harris, J. A.
Gravitationalwave signal of a corecollapse supernova explosion of a
15 M$_{â˜‰}$ star}
Phys. Rev. D102.023027 (2020)
Powell, J. and Müller, B.
Threedimensional corecollapse supernova simulations of massive and
rotating progenitors
MNRAS 494, 4665 (2020)
Shibagaki, S. and Kuroda, T. and Kotake, K. and Takiwaki, T.
A new gravitationalwave signature of lowT/W instability in rapidly
rotating stellar core collapse
MNRAS 493, L138 (2020)
Sotani, H. and Takiwaki, T.
Dimension dependence of numerical simulations on gravitational waves
from protoneutron stars
Phys. Rev. D102.023028 (2020)
Vartanyan, D. and Burrows, A.
Gravitational Waves from Neutrino Emission Asymmetries in
Corecollapse Supernovae
ApJ 901, 2 (2020)
Warren, M.L. and Couch, S.M. and O'Connor, E.P. and Morozova, V.
Constraining Properties of the Next Nearby Corecollapse Supernova
with Multimessenger Signals
ApJ 898, 139 (2020)
Zha, S. and O'Connor, E.P. and Chu, MC. and Lin, LM. and Couch, S.M.
Gravitationalwave Signature of a Firstorder Quantum Chromodynamics
Phase Transition in CoreCollapse Supernovae
Phys. Rev. Lett. 125.051102 (2020)
2019
Andresen, H. and Müller, E. and Janka, H.T. and Summa, A. and
Gill, K. and Zanolin, M.
Gravitational waves from threedimensional corecollapse supernova models:
The impact of moderate progenitor rotation
MNRAS 486, 2238 (2019)
Pajkos, M.A. and Couch, S.M. and Pan, K.C. and O'Connor, E.P.
Features of Accretion Phase Gravitational Wave Emission from
Twodimensional Rotating CoreCollapse Supernovae
ApJ 878, 13 (2019)
Powell, J. and Müller, B.
Gravitational Wave Emission from 3D Explosion Models of CoreCollapse
Supernovae with Low and Normal Explosion Energies
MNRAS 487, 1178 (2019)
Radice, D. and Morozova, V. and Burrows, A. and Vartanyan, D. and
Nagakura,H.
Characterizing the Gravitational Wave Signal from
CoreCollapse Supernovae
ApJL 876, L9 (2019)
Roma, V. and Powell, J. and Heng, I.~S. and Frey, R.
Astrophysics with corecollapse supernova gravitational wave signals
in the next generation of gravitational wave detectors
Phys. Rev. D99, 060318 (2019)
Sotani, H.
Gravitational waves from protoneutron stars and nuclear equation of
state
Astron. Nachrichten 340 217220 (2019)
Sotani, H. and Kuroda, T. and Takiwaki, T. and Kotake, K.
Dependence of the outer boundary condition on protoneutron star
asteroseismology with gravitationalwave signatures
Phys. Rev. D99, 123024 (2019)
Srivastava, V. and Ballmer, S. and Brown, D.A. and Afle, C. and Burrows, A.
Radice, D. and Vartanyan, D.
Detection Prospects of CoreCollapse Supernovae with
SupernovaOptimized ThirdGeneration Gravitationalwave Detectors
Phys. Rev. D100, 043026 (2019)
Suvorova, S. and Powell, J. and Melatos, A.
Reconstructing gravitational wave corecollapse supernova signals with
dynamic time warping
Phys. Rev. D99, 123012 (2019)
TorresForne, A. and CerdaDuran, P. and Passamonti, A. and
Obergaulinger, M. and Font, J.A.
Towards asteroseismology of corecollapse supernovae with
gravitationalwave observations  II. Inclusion of spacetime
perturbations
MNRAS 482, 3967 (2019)
TorresForne, A. and CerdaDuran, P. and Obergaulinger, M. and
Müller, B. and Font, J.A.
Universal Relations for GravitationalWave Asteroseismology of
Protoneutron Stars
Phys. Rev. Lett. 123, 051102 (2019)
WesternacherSchneider, J.R. and O'Connor, E. and O'Sullivan, E. and
Tamborra, I. and Wu, M.R. and Couch, S.M. and Malmenbeck, F.
Multimessenger Asteroseismology of CoreCollapse Supernovae
Phys. Rev. D100.123009 (2019)
Vartanyan, D. and Burrows, A. and Radice, D.
Temporal and Angular Variations of 3D CoreCollapse Supernova
Emissions and their Physical Correlations
MNRAS 489, 2227 (2019)
2018
Astone, P. and CerdaDuran, P. and Di Palma, I. and
Drago, M. and Muciaccia, F. and Palomba, C. and Ricci, F.
New method to observe gravitational waves emitted by core collapse
supernovae
Phys. Rev. D98, 122002 (2018)
Hayama, K. and Kuroda, T. and Kotake, K. and Takiwaki, T.
Circular polarization of gravitational waves from nonrotating
supernova cores: a new probe into the preexplosion hydrodynamics
MNRAS 477, L96 (2018)
Kawahara, H. and Kuroda, T. and Takiwaki, T. and Hayama, K. and
Kotake, K.
A Linear and Quadratic TimeFrequency Analysis of Gravitational
Waves from CoreCollapse Supernovae
ApJ 867, 126 (2018)
Morozova, V. and Radice, D. and Burrows, A. and Vartanyan, D.
The gravitational wave signal from corecollapse supernovae
ApJ 861, 10 (2018)
O'Connor, E.P. and Couch, S.M.
Exploring Fundamentally Threedimensional Phenomena in Highfidelity
Simulations of Corecollapse Supernovae
ApJ 865, 81 (2018)
Pan, K.C. and Liebendörfer, M. and Couch, S.M. and Thielemann, F.K.
Equation of State Dependent Dynamics and Multimessenger Signals from
Stellarmass Black Hole Formation
ApJ 857, 13 (2018)
Powell, J.
Parameter Estimation and Model Selection of Gravitational Wave Signals
Contaminated by Transient Detector Noise Glitches
CQG 35, 155017 (2018); eprint, arXiv:1812.05738
Takiwaki, T. and Kotake, K.
Anisotropic emission of neutrino and gravitationalwave signals from
rapidly rotating corecollapse supernovae
MNRAS 475, L91 (2018)
TorresForne, A. and CerdaDuran, P. and Passamonti, A. and Font, J.A.
Towards asteroseismology of corecollapse supernovae with
gravitationalwave observations  I. Cowling approximation
MNRAS 474, 5272 (2018)
2017
Andresen, H. and Müller, B. and Müller, E. and Janka, H.T.
Gravitational Wave Signals from 3D Neutrino Hydrodynamics Simulations
of CoreCollapse Supernovae
MNRAS 468, 2032 (2017)
Crocker, K. and Prestegard, T. and Mandic, V. and Regimbau, T. and
Olive, K. and Vangioni, E.
A Systematic Study of the Stochastic GravitationalWave Background
due to Stellar Core Collapse
Phys. Rev. D95, 063015 (2017)
Kotake, K. and Kuroda, T.
Gravitational Waves from CoreCollapse Supernovae
Handbook of Supernovae, Springer, 2017, p.1671
Kuroda, T. and Kotake, K. and Hayama, K. and Takiwaki, T.
Correlated Signatures of GravitationalWave and Neutrino Emission
in ThreeDimensional
GeneralRelativistic CoreCollapse Supernova Simulations
ApJ 851, 62 (2017)
Powell, J. and Szczepanczyk, M. and Heng, I.S.
Inferring the corecollapse supernova explosion mechanism with
threedimensional gravitationalwave simulations
Phys. Rev. D96, 123013 (2017)
Richers, S. and Ott, C.D. and Abdimaklaov, E. and O'Connor, E. and
Sullivan, C.
Equation of State Effects on Gravitational Waves from Rotating Core
Collapse
Phys. Rev. D95, 063019 (2017)
Yakunin, K.N. and Mezzacappa, A. and Marronetti, P. and Lentz,
E.J. and Bruenn, S.W. and
Hix, W.R. and Messer, O.E.B. and Endeve, E. and Blondin, J.M. and
Harris, J.A.
The Gravitational Wave Signal of a Core Collapse Supernova Explosion
of a 15 Solar Mass Star
eprint arXiv:1701.07325
2016
Abbott, B.P. and ... (LIGO collaboration)
A First Targeted Search for GravitationalWave Bursts from
CoreCollapse Supernovae in Data of
FirstGeneration Laser Interferometer Detectors
of CoreCollapse Supernovae
Phys. Rev. D94.102001 (2016)
Gossan, S.E. and Sutton, P. and Stuver, A. and Zanolin, M. and Gill,
K. and Ott, C. D.
Observing Gravitational Waves from CoreCollapse Supernovae in the
Advanced Detector Era
Phys. Rev. D93.042002 (2016)
Hayama, K. and Kuroda, T. and Nakamura, K. and Yamada, S.
Circular Polarizations of Gravitational Waves from CoreCollapse Supernovae:
A Clear Indication of Rapid Rotation
Phys. Rev. Lett., 116.151102 (2016)
Heo, J.E. and Yoon, S. and Lee, D.S. and Kong, I.t. and Lee, S.H.
and van Putten, M.H.P.M. and Della Valle, M.
Proposed searches for candidate sources of gravitational waves in a nearby
corecollapse supernova survey
New Astronomy, 42, 24 (2016)
Kuroda, T. and Kotake, K. and Takiwaki, T.
A new gravitationalwave signature of SASI activities in nonrotating
supernova cores
ApJL 829, L14 (2016)
Powell, J and Gossan, S.E. and Logue, J. and Heng, I.S.
Inferring the corecollapse supernova explosion mechanism with
gravitational waves
Phys. Rev. D94, 123012 (2016)
Sotani, H. and Takiwaki, T.
Gravitational wave asteroseismology with protoneutron stars
Phys. Rev. D94, 044043 (2016)
van Putten, M.H.P.M.
Directed Searches for Broadband Extended Gravitational Wave Emission
in Nearby Energetic Corecollapse Supernovae
ApJ 819, 169 (2016)
2015
Fuller, J. and Klion, H. and Abdikamalov, E. and Ott, C.D.
Supernova seismology: gravitational wave signatures of rapidly
rotating core collapse
MNRAS 450, 414 (2015)
Hayama, K. and Kuroda, T. and Kotake, K. and Takiwaki, T.
Coherent Network Analysis of Gravitational Waves from
ThreeDimensional CoreCollapse Supernova Models
Phys. Rev. D92, 212001 (2015)
Levinson, A. and van Putten, M.H.P.M. and Pick, G
Broadband Extended Emission in Gravitational Waves from
Corecollapse Supernovae
ApJ 812, 124 (2015)
Yakunin, K.N. and Mezzacappa, A. and Marronetti, P. and Yoshida, S.
and Bruenn, S.W. and Hix, W.R. and Lentz, E.J. and Messer, O.E.B.
and Harris, J.A. and Endeve, E. and Blondin, J.M. and Lingerfelt, E.J.
Gravitational Wave Signatures of Ab Initio TwoDimensional Core
Collapse Supernova Explosion Models for 1225 Solar Masses Stars
Phy. Rev. D92, 084040 (2015)
Yokozawa, T. and Asano, M. and Kayano, T. and Suwa, Y. and
Kanda, N. and {oshio, Y. and Vagins, M.R.
Probing the Rotation of Corecollapse Supernova with a Concurrent Analysis
of Gravitational Waves and Neutrinos
ApJ 811, 86 (2015)
2014
Abdikamalov, E. and Gossan, S. and DeMaio, A.M. and Ott, C.D.
Measuring the Angular Momentum Distribution in CoreCollapse
Supernova Progenitors with Gravitational Waves
Phys. Rev. D90, 044011 (2014)
Edwards, M.C. and Meyer, R. and Christensen, N.
Bayesian parameter estimation of core collapse supernovae using
gravitational wave simulations
Inverse Problems, Volume 30, Issue 11, article id. 114008 (2014)
Engels, W.J. and Frey, R. and Ott, C.D.
Multivariate Regression Analysis of Gravitational Waves from
Rotating Core Collapse
Phys. Rev. D90, 124026 (2014)
Kuroda, T. and Takiwaki, T. and Kotake, K.
Gravitational wave signatures from lowmode spiral instabilities
in rapidly rotating supernova cores
Phys. Rev. D89, 044011 (2014)
2013
CerdaDuran, P. and DeBrye, N. and Aloy, M.A. and Font,
J.A. and Obergaulinger, M.
Gravitational Wave Signatures in Black Hole Forming Core Collapse
ApJL 779, L18 (2013)
Kotake, K.
Multiple physical elements to determine the gravitationalwave
signatures of corecollapse supernovae
Comptes Rendus Physique 14 (2013) 318
Müller, B. and Janka, HTh. and Marek, A.
A New MultiDimensional General Relativistic Neutrino Hydrodynamics
Code of CoreCollapse Supernovae
III. Gravitational Wave Signals from Supernova Explosion Models
ApJ 766, 43 (2013)
Ott, C.D. and Abdikamalov, E. and Moesta, P. and Haas, R. and Drasco,
S. and O'Connor, E. and Reisswig, C. and Meakin, C. and Schnetter, E.
GeneralRelativistic Simulations of ThreeDimensional CoreCollapse
Supernovae
ApJ 768, 115 (2013)
Wongwathanarat, A. and Janka, H.T. and Müller, E.
Threedimensional neutrinodriven supernovae: Neutron star kicks,
spins, and asymmetric ejection of nucleosynthesis products
A&A 552, 126 (2013)
2012
Janka, H.T.
Explosion Mechanisms of CoreCollapse Supernovae
Ann. Rev. Nuc. Part. Sci. 62, 407 (2012)
Kotake, K. and Takiwaki, T. and Harikae, S.
Gravitational Wave Signatures of Hyperaccreting Collapsar Disks
ApJ 755, 84 (2012)
Kotake, K. and Takiwaki, T. and Suwa, Y. and Iwakami Nakano, W. and
Kawagoe, S. and Masada, Y. and Fujimoto, S.I.
Multimessengers from corecollapse supernovae: multidimensionality as
a key to bridge theory and observation
Advances in Astronomy 2012, 428757 (2012)
Logue, J. and Ott, C.D. and Heng, I.S. and Kalmus,P. and Scargill, J.
Inferring CoreCollapse Supernova Physics with Gravitational Waves
Phys. Rev. D86, 044023 (2012)
Müller, E. and Janka, HTh. and Wongwathanarat, A.
Parametrized 3D models of neutrinodriven supernova explosions:
Neutrino emission asymmetries and gravitationalwave signals
A&A 537, 63 (2012)
Ott, C.D. and Abdikamalov, E. and O'Connor, E.P. and Reisswig, C.
and Haas, R. and Kalmus, P. and Drasco, S. and Burrows, A. and
Schnetter, E.
Correlated Gravitational Wave and Neutrino Signals from
GeneralRelativistic Rapidly Rotating Iron Core Collapse
Phys. Rev. D86, 024026 (2012)
Piro, A.L. and Thrane, E.
Gravitational Waves from Fallback Accretion onto Neutron Stars
ApJ 761, 63 (2012)
2011
Fryer, C. L. and New, K.C.B.
Gravitational Waves from Gravitational Collapse
Living Reviews in Relativity, 14 (2011), 1.
Kotake, K. and Iwakami Nakano, W. and Ohnishi, N.
Effects of Rotation on Stochasticity of Gravitational Waves in
Nonlinear Phase of CoreCollapse Supernovae
ApJ 736, 124 (2011)
Ott, C. D. and Reisswig, C. and Schnetter, E. and O'Connor, E. and
Sperhake, U. and LÃ¶ffler, F. and Diener, P. and
Abdikamalov, E. and Hawke, I. and Burrows, A.
Dynamics and Gravitational Wave Signature of Collapsar Formation
Phys. Rev. Lett. 106, 161103 (2011)
Reisswig, C. and Ott, C.D. and Sperhake, U. and Schnetter, E.
Gravitational Wave Extraction in Simulations of Rotating Stellar
Core Collapse
Phys. Rev. D83, 064008 (2011)
Takiwaki, T. and Kotake, K.
Gravitational Wave Signatures of Magnetohydrodynamically Driven
Corecollapse Supernova Explosions
ApJ 743, 30 (2011)
Zhu, X.J. and Howell, E. and Blair, D.
Observational upper limits on the gravitational wave production of
core collapse supernovae
MNRAS 409, L132 (2010)
2010
Abdikamalov, E.B. and Ott, C.D. and Rezzolla, L. and Dessart, L. and
Dimmelmeier, H. and Marek, A. and Janka, H.T.
Axisymmetric general relativistic simulations of the accretioninduced
collapse of white dwarfs
Phys. Rev. D81, 044012 (2010)
Leonor, I. and Cadonati, L. and Coccia, E. and D'Antonio, S. and
Di Credico, A. and Fafone, V. and Frey, R. and Fulgione, W. and
Katsavounidis, E. and Ott, C.D. and Pagliaroli, G. and
Scholberg, K. and Thrane, E. and Vissani, F.
Searching for prompt signatures of nearby corecollapse supernovae
by a joint analysis of neutrino and gravitational wave data
CQG, 27, 084019 (2010)
Scheidegger, S. and KÃ¤ppeli, R. and Whitehouse, S.C. and Fischer, T. and
LiebendÃ¶rfer, M.
The influence of model parameters on the prediction of gravitational
wave signals from stellar core collapse
A&A 514, A51 (2010)
Scheidegger, S. Whitehouse, S.C. and KÃ¤ppeli, R. and LiebendÃ¶rfer, M.
Gravitational waves from supernova matter
CQG, 27, 114101 (2010)
Yakunin, K.N and Marronetti, P. and Mezzacappa, A. and Bruenn, S.W and
Lee, C.T. and Chertkow, M. and Hix, W. and
Blondin, J.M and Lentz, E.J and Messer, B. and Yoshida, S.
Gravitational Waves from Core Collapse Supernovae
QCG 27, 194005 (2010)
Zhu, X.J. and Howell, E. and Blair, D.
Observational upper limits on the gravitational wave production
of core collapse supernovae
MNRAS 409, L132 (2010)
2009
Halzen, F. and Raffelt, G.
Reconstructing the supernova bounce time with neutrinos in IceCube
Phys. Rev. D80, 087301 (2009)
Kotake, K. and Iwakami, W. and Ohnishi, N. and Yamada, S.
Stochastic nature of gravitational waves from supernova explosions
with standing accretion shock instability
ApJ 697, L133 (2009)
Kotake, K. and Iwakami, W. and Ohnishi, N. and Yamada, S.
RayTracing analysis of anisotropic neutrino radiation for estimating
gravitational waves in corecollapse supernovae
ApJ 704, 951 (2009)
Marek, A. and Janka, H.T. and Müller, E.
Equationofstate dependent features in shockoscillation modulated
neutrino and gravitationalwave signals from supernovae
A&A 496, 475 (2009)
Murphy, J. and Ott, C.D. and Burrows, A.
A model for gravitational wave emission from neutrinodriven
corecollapse supernovae}
ApJ 707, 1173 (2009)
Ott, C.D.
The gravitationalwave signature of corecollapse supernovae
Topical Review, CQG 26, 063001 (2009)
Ott, C.D.
Probing the corecollapse supernova mechanism with gravitational waves
CQG, 26, 204015 (2009)
Ott, C.D. and Schnetter, E. and Burrows, A. and Livne, E. and
O\'Connor, E. and Löffler, F.
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