Selected List of Recent Princeton University Supernova and Merger Publications

Click on the titles for links to the papers

Supernova Theory Papers:

  • "Physical Correlations and Predictions Emerging from Modern Core-Collapse Supernova Theory," Adam Burrows, Tianshu Wang, and David Vartanyan,, Ap.J. Letters, 964, L16, 2024.

  • "A Theory for Neutron Star and Black Hole Kicks and Induced Spins," Adam Burrows, Tianshu Wang, David Vartanyan, and Matthew Coleman,, Ap.J., 963, 63, 2024.

  • "Nucleosynthetic Analysis of Long-Term Three-Dimensional Core-Collapse Supernova Simulations," Tianshu Wang and Adam Burrows,, Ap.J., 962, 71, 2024.

  • "Black-Hole Formation Accompanied by the Supernova Explosion of a 40-Solar--Mass Progenitor," Adam Burrows, David Vartanyan, and Tianshu Wang,, Ap.J., 957, 68, 2023.

  • "Neutrino Signatures of One Hundred 2D Axisymmetric Core-Collapse Supernova Simulations," David Vartanyan and Adam Burrows,, MNRAS, 526, 5900-5910, 2023.

  • "Neutrino-Driven Winds in Three-Dimensional Core-Collapse Supernova Simulations," Tianshu Wang and Adam Burrows,, Ap.J., 954, 114, 2023.

  • "The Gravitational-Wave Signature of Core-Collapse Supernovae," (David Vartanyan, Adam Burrows, Tianshu Wang, Matthew Coleman, and Christopher White),, Phys. Rev. D, 107, 103015, 2023.

  • "Effects of Different Closure Choices in Core-Collapse Supernova Simulations," (Tianshu Wang and Adam Burrows), Ap.J., 943, 78, 2023.

  • "Kicks and Induced Spins of Neutron Stars at Birth," (Matthew S.B. Coleman and Adam Burrows), MNRAS, 517, 3938-3961, 2022.

  • "Applications of Machine Learning to Predicting Core-collapse Supernova Explosion Outcomes," (Benny Tsz-Ho Tsang, David Vartanyan, and Adam Burrows), accepted to Ap.J. (Letters), 2022.

  • "The Essential Character of the Neutrino Mechanism of Core-Collapse Supernova Explosions," (Tianshu Wang, David Vartanyan, Adam Burrows, and Mathew S.B. Coleman), accepted to MNRAS, 2022.

  • "The Collapse and Three-Dimensional Explosion of Three-Dimensional Massive-star Supernova Progenitors," (D. Vartanyan, M.S.B. Coleman, and Adam Burrows), MNRAS, 510, 4689-4705, 2022.

  • "On the Origin of Pulsar and Magnetar Magnetic Fields," (Christopher J. White, Adam Burrows, Matthew S.B. Coleman, and David Vartanyan), Ap. J., 926, 111, 2022.

  • "Core-Collapse Supernova Explosion Theory," (Adam Burrows and David Vartanyan), Nature, 589, 29-39, 2021.

  • "Supernova neutrino signals based on long-term axisymmetric simulations, (H. Nagakura, Adam Burrows, and David Vartanyan) , MNRAS, 506, 1462-1479, 2021.

  • "A Generalized Kompaneets Formalism for Inelastic Neutrino-Nucleon Scattering in Supernova Simulations," (Tianshu Wang and A. Burrows), Phys. Rev D102, 023017, 2020.

  • "A Generalized Kompaneets Formalism for Inelastic Neutrino-Nucleon Scattering in Supernova Simulations," (Tianshu Wang and A. Burrows), Phys. Rev D102, 023017, 2020.

  • "Core-collapse supernova neutrino emission and detection informed by state-of-the-art three-dimensional numerical models," (H. Nagakura, A. Burrows, D. Vartanyan, and D. Radice), Mon. Not. Royal Astron. Soc., 500, 696, 2020.

  • "Gravitational Waves from Neutrino Emission Asymmetries in Core-Collapse Supernovae," (David Vartanyan and Adam Burrows), Ap.J., 901, 108, 2020.

  • "A Systematic Study of Proto-Neutron Star Convection in Three-Dimensional Core-Collapse Supernova Simulations," (Hiroki Nagakura, Adam Burrows, David Radice, and David Vartanyan), Mon. Not. Royal Astron. Soc., 492, 576, 2020.

  • "The Overarching Framework of Core-Collapse Supernova Explosions as Revealed by 3D Fornax Simulations," (Adam Burrows, David Radice, David Vartanyan, Hiroki Nagakura, M. Aaron Skinner, & Joshua C. Dolence), Mon. Not. Royal Astron. Soc., 491, 2715, 2019.

  • "Temporal and Angular Variations of 3D Core-Collapse Supernova Emissions and their Physical Correlations," (David Vartanyan, Adam Burrows, and David Radice), Monthly Notices of the Royal Astronomical Society, 489, 2227, 2019.

  • "Detection Prospects of Core-Collapse Supernovae with Supernova-Optimized Third-Generation Gravitational-wave Detectors," (Varun Srivastava, Stefan Ballmer, Duncan A. Brown, Chaitanya Afle, Adam Burrows, David Radice, and David Vartanyan), Physical Review D, 100.043026, 2019.

  • "Towards an Understanding of the Resolution Dependence of Core-Collapse Supernova Simulations," (H. Nagakura, A. Burrows, D. Radice, and D. Vartanyan), Monthly Notices of the Royal Astronomical Society, 490, 4622, 2019.

  • "Three-Dimensional Supernova Explosion Simulations of 9-, 10-, 11-, 12-, and 13-Msun Stars," (Adam Burrows, David Radice, & David Vartanyan), Monthly Notices of the Royal Astronomical Society, 482, 351, 2019.

  • "A Brief History of the Co-evolution of Supernova Theory with Neutrino Physics," (Adam Burrows), a contribution to the Proceedings of the Conference on the History of the Neutrino, eds. Jacques Dumarchez, Michel Cribier, and Daniel Vignaud, held in Paris France, Sept. 7-9, 2018.

  • "Characterizing the Gravitational Wave Signal from Core-Collapse Supernovae," (David Radice, Viktoriya Morozova, Adam Burrows, David Vartanyan, & Hiroki Nagakura), Ap.J. Letters, 876, L9, 2019.

  • "Comparing Treatments of Weak Reactions with Nuclei in Simulations of Core-collapse Supernovae," (Hiroki Nagakura, Shun Furusawa, Hajime Togashi, Sherwood Richers, Kohsuke Sumiyoshi, & Shoichi Yamada), Ap.J. Supplement, 240, 38, 2019.

  • "Linear Analysis of Fast-Pairwise Collective Neutrino Oscillations in Core-Collapse Supernovae based on the Results of Boltzmann Simulations," (Milad Azari-Delfan, Shoichi Yamada, Taiki Morinaga, Wakana Iwakami, Hiroki Nagakura, & Kohuke Sumiyoshi), submitted to Phys. Rev. D, 2019.

  • "A Successful 3D Core-Collapse Supernova Explosion Model," (D. Vartanyan, A. Burrows, D. Radice, A. Skinner, & J. Dolence), Mon. Notices R.A.S., 482, 351, 2019.

  • "Fornax: A Flexible Code for Multiphysics Astrophysical Simulations," (M. Aaron Skinner, Joshua Dolence, Adam Burrows, David Radice, & David Vartanyan), Astrophys. J. Supplement Series, 241, 7, 2019.

  • "Neutrino Signals of Core-Collapse Supernovae in Underground Detectors," (Shaquann Seadrow, Adam Burrows, David Vartanyan, David Radice, & M. Aaron Skinner), Monthly Notices of the RAS, 480, 4710, 2018.

  • "Revival of the Fittest: Exploding Core-Collapse Supernovae from 12 to 25 M solar masses," Monthly Notices of the Royal Astronomical Society, 477, 3091, 2018.

  • "The Gravitational Wave Signal from Core-Collapse Supernovae," (Viktoriya Morozova, David Radice, Adam Burrows, & David Vartanyan), Astrophys. J., 861, 10, 2018.

  • "Electron-Capture and Low-Mass Iron-Core-Collapse Supernovae: New Neutrino-Radiation-Hydrodynamics Simulations," (David Radice, Adam Burrows, David Vartanyan, M. Aaron Skinner, & Joshua C. Dolence), Astrophys. J., 850, 43, 2017.

  • "Crucial Physical Dependencies of the Core-Collapse Supernova Mechanism", (Adam Burrows, David Vartanyan, Joshua Dolence, M. Aaron Skinner, and David Radice), Space Science Reviews, 214, 33, 2018.

  • "The impact of vorticity waves on the shock dynamics in core-collapse supernovae," (Cesar Huete, Ernazar Abdikamalov, David Radice) accepted to MNRAS, 2017

  • "Turbulence in Core-Collapse Supernovae," (David Radice, Ernazar Abdikamalov, Christian D. Ott, Philipp Moesta, Sean M. Couch, Luke F. Roberts) Invited review for J. Phys. G special issue: "Focus on microphysics in core-collapse supernovae: 30 years since SN1987A," 2017

  • "Should One Use the Ray-by-Ray Approximation in Core-Collapse Supernova Simulations?", (M. Aaron Skinner, A. Burrows , & J.C. Dolence), Astrophys. J., 831, 81, 2016.

  • "The Supernova Breakout Burst Detection Potential of Terrestrial Neutrino Detectors," (Joshua Wallace, Adam Burrows, & J. Dolence), Astrophys. J., 808, 172, 2015.

  • "Baade & Zwicky: Super-Novae, Neutron Stars, and Cosmic Rays," (Adam Burrows), Proceedings of the National Academy of Sciences, 112, no. 5, pp. 1241-1242 (2015).

  • "Two-Dimensional Core-Collapse Supernova Models with Multi-Dimensional Transport," (Josh Dolence, Adam Burrows, & Weiqun Zhang), Astrophys. J., 800, 10, 2015.

  • "Perspectives on Core-Collapse Supernova Theory," (Adam Burrows), Reviews of Modern Physics, 85, 275, 2013.

  • "Dimensional Dependence of the Hydrodynamics of Core-Collapse Supernovae," (J. Dolence, A. Burrows, J. Murphy, & J. Nordhaus), Astrophys. J., 765, 110, 2013.

  • "CASTRO: A New Compressible Astrophysical Solver. III. Multigroup Radiation Hydrodynamics," (W. Zhang, L. Howell, A. Almgren, A. Burrows, J. Dolence, & J. Bell), Astrophys. J. Suppl., 204, 7, 2013.

  • "The Dominance of Neutrino-Driven Convection in Core-Collapse Supernovae," (J. W. Murphy, J. Dolence, & A. Burrows), Astrophys. J., 771, 52, 2013.

  • "An Investigation into the Character of Pre-Explosion Core-Collapse Supernova Shock Motion," (Adam Burrows, Joshua Dolence, & Jeremiah Murphy), Astrophys. J., 759, 5, 2012.

  • "A New Monte Carlo Method for Time-Dependent Neutrino Radiation Transport," (E. Abdikamalov, A. Burrows, C.D. Ott et al.), Astrophys. J., 755, 111, 2012.

    • Neutron-Star Merger Papers:

  • "Full Transport Disk Model Unveils the Blue Kilonova in GW170817," (Jonah Miller, Ben Ryan, Joshua C. Dolence, Adam Burrows, Chris Fontes, Chris Fryer, Oleg Korobkin, Jonas Lippuner, Matthew Mumpower, and Ryan T. Wollaeger), Phys. Rev. D, 100, 023008, 2019.

  • "Probing Extreme-Density Matter with Gravitational Wave Observations of Binary Neutron Star Merger Remnants," (David Radice, Sebastiano Bernuzzi, Walter Del Pozzo, Luke F. Roberts, Christian D. Ott), Astrophys. J., 842, L10, 2017

  • "General-Relativistic Large-Eddy Simulations of Binary Neutron Star Mergers," (David Radice), Astrophys. J., 838, L2, 2017

  • "AT2017gfo: an anisotropic and three-component kilonova counterpart of GW170817," (Albino Perego, David Radice, Sebastiano Bernuzzi), Astrophys. J., 850, L37, 2017

  • "GW170817: Joint Constraint on the Neutron Star Equation of State from Multimessenger Observations," (David Radice, Albino Perego, Francesco Zappa, Sebastiano Bernuzzi), Astrophys. J., 852, L29, 2017

  • "Gravitational-wave luminosity of binary neutron stars mergers," (Francesco Zappa, Sebastiano Bernuzzi, David Radice, Albino Perego, Tim Dietrich), Phys. Rev. Lett., 120, 111101, 2018

  • "Long-lived Remnants from Binary Neutron Star Mergers," (David Radice, Albino Perego, Sebastiano Bernuzzi, Bing Zhang), Submitted to Monthly Notices of the RAS, 2018

  • "CoRe database of binary neutron star merger waveforms and its application in waveform development," (Tim Dietrich, David Radice, Sebastiano Bernuzzi, Francesco Zappa, Albino Perego, Bernd Brueugmann, Swami Vivekanandji Chaurasia, Reetika Dudi, Wolfgang Tichy, Maximiliano Ujevic), Submitted to Phys. Rev. Lett., 2018

  • "Time-domain effective-one-body gravitational waveforms for coalescing compact binaries with nonprecessing spins, tides and self-spin effects," (Alessandro Nagar, Sebastiano Bernuzzi, Walter Del Pozzo, Gunnar Riemenschneider, Sarp Akcay, Gregorio Carullo, Philipp Fleig, Stanislav Babak, Ka Wa Tsang, Marta Colleoni, Francesco Messina, Geraint Pratten, David Radice, Piero Rettegno, Michalis Agathos, Edward Fauchon-Jones, Mark Hannam, Sascha Husa, Tim Dietrich, Pablo Cerda-Duran, Jose A. Font, Francesco Pannarale, Patricia Schmidt, Thibault Damour), Submitted to Phys. Rev. D, 2018