The Net Advance of Physics:
SUPERNOVAE:

SUPERNOVAE:

• General: Introductory: R. Nave's HyperPhysics site; RGO 96;
• General: Schommer et al. 99/09; Wheeler 99/12; Livio 2000/05; Wheeler 2002/09; Turatto 2003/01;
  • Supernova Classes and Subclasses by M. Turatto et al. [2007/06]
  • Physics of Supernovae: theory, observations, unresolved problems by D. K. Nadyozhin [2007/09]
  • A "Crib Sheet" for Supernova Events by David Arnett [2008/06]
  • Astrophysical Explosions: From Solar Flares to Cosmic Gamma-ray Bursts by J. Craig Wheeler [2011/11]
  • The expansion of the universe observed with supernovae by Pierre Astier [Reports on Progress in Physics 75, 116901 (2012)]
  • The First Ten Years of Swift Supernovae by Peter J. Brown et al. [2015/04]
  • Observational and Physical Classification of Supernovae by Avishay Gal-Yam [2016/11]
  • The Supernova--Supernova Remnant Connection by David Milisavljevic and Robert A. Fesen [2017/01]
  • Physics of Radiation-Mediated Shocks and Its Application to GRBs, supernovae, and neutron star mergers. by Amir Levinson and Ehud Nakar [2019/09]
  • Equation of state in neutron stars and supernovae by K. Sumiyoshi et al. [2022/07]

• General: Homepages: Montes; Saizar;
• General: Data: Specific Supernovae (Net Advance) 96/12;
• General: MECHANISMS: Balantekin and Haxton 99/03;

• General: NUMERICAL SIMULATIONS: Cardall 2002/12;
  • Massive Computation for Understanding Core-Collapse Supernova Explosions by Christian D. Ott [Computing in Science and Engineering 18(5), 78 (2016)]
  • Supernova simulations by B. Müller [2024/03]

• General: SEARCHES: Lee 2000/08;

• General: SPECIFIC SUPERNOVAE:
  • Supernova 1604, Kepler's supernova, and its remnant by Jacco Vink [2016/12]

• Types: Cappellaro and Turatto 2000/12;

• Type: CORE COLLAPSE: Hamuy 2003/01; Haxton 2003/01;
  • Explosion Mechanisms of Core-Collapse Supernovae by Hans-Thomas Janka [2012/06]
  • The Deaths of Very Massive Stars by Stan E. Woosley and Alexander Heger [2014/06]
  • Resolved Host Studies of Stellar Explosions by Emily M. Levesque [2016/02]
  • The Status of Multi-Dimensional Core-Collapse Supernova Models by Bernhard Müller [2016/08]
  • Massive Computation for Understanding Core-Collapse Supernova Explosions by Christian D. Ott [Computing in Science and Engineering 18(5), 78 (2016)]
  • The Core-Collapse Supernova Mechanism by Bernhard Müller [2017/02]
  • Turbulence in Core-Collapse Supernovae by David Radice et al. [2017/10]
  • Hydrogen-rich Core Collapse Supernovae by Iair Arcavi [2017/10]
  • Neutron Star Formation and Core Collapse Supernovae by Pablo Cerdá-Durán and Nancy Elias-Rose [2018/06]
  • Core-collapse supernova explosion theory by A. Burrows and D. Vartanyan [2020/09]
  • Stellar evolution, SN explosion, and nucleosynthesis by K. Maeda [2022/10]
  • Gravitational waves from core-collapse supernovae by E. Abdikamalov et al. [2020/10]
  • Nuclei in core-collapse supernovae engine by S. Furusawa and H. Nagakura [2022/11]
  • The physics of core-collapse supernovae: Explosion mechanism and explosive nucleosynthesis by L. Boccioli and L. Roberti [2024/03]

• Type: Ia: Niemeyer et al. 2002/03;
  • Type-Ia supernovae: new clues to their progenitors from the delay-time distribution by Dan Maoz [2010/07]
  • A Review of Type Ia Supernovae as Stellar Endpoints and Cosmological Tools by D. Andrew Howell [2010/11]
  • Near-Infrared Properties of Type Ia Supernovae by Mark M. Phillips [2011/11]
  • Progenitors of type Ia supernovae by Bo Wang and Zhanwen Han [2012/04]
  • Progenitors of type Ia supernovae by Keiichi Maeda and Yukikatsu Terada [International Journal of Modern Physics D 25, 1630024 (2016)]
  • Type Ia Supernovae: Where Are They Coming From, And Where Will They Lead Us? by Ferdinando Patat and Na'ama Hallakoun [2017/07]
  • Mass-accreting white dwarfs and type Ia supernovae by Bo Wang [2018/01]
  • Surviving Companions of Type Ia Supernovae: Theory and Observations by Pilar Ruiz-Lapuente [2018/12]
  • Observational Properties of Thermonuclear Supernovae by Saurabh W. Jha et al. [Nature Astronomy 3, 706 (2019)]
  • Type Ia Supernova Sub-Classes and Progenitor Origin by A. J. Ruiter [2020/01]
  • Type Ia Supernova Explosions in Binary Systems by Z.-W. Liu et al. [2023/05]

• Type: Iax:
  • Type Iax Supernovae by Saurabh W. Jha [2017/07]

• Type: Ib:
  • Interacting Supernovae: Types IIn and Ibn by Nathan Smith [2016/12]

• Type: II:
  • Interacting Supernovae: Types IIn and Ibn by Nathan Smith [2016/12]

• Type: FAINT: Schommer et al. 99/09;

• Type: HIGH REDSHIFT: Kim 98/05;

• Type: HYPERNOVAE: Nomoto et al. 2002/09;
  • Ultra-high Energy Cosmic Rays and Neutrinos from Gamma-Ray Bursts, Hypernovae and Galactic Shocks by P. Mészáros [2014/03]

• Type: LUMINOUS:
  • Luminous Supernovae by Avishay Gal-Yam [2012/08]

• Type: PECULIAR:
  • Peculiar Supernovae by Dan Milisavljevic and Raffaella Margutti [Space Science Reviews 214, 68 (2018)]

• Type: SUPERLUMINOUS:
  • The Energy Sources of Superluminous Supernovae by S. Q. Wang et al. [2019/02]
  • Superluminous supernovae by Takashi J. Moriya et al. [2018/03]
  • Observational Properties of Extreme Supernovae by Cosimo Inserra [Nature Astronomy 3, 697 (2019)]
  • Physics of Superluminous Supernovae by K.-J. Chen [2021/03]
  • Superluminous supernovae: An explosive decade by M. Nicholl [2021/09]

• Type: THERMONUCLEAR:
  • The Extremes of Thermonuclear Supernovae by Stefan Taubenberger [2017/03]
  • Combustion in thermonuclear supernova explosions by Friedrich K. Roepke [2017/03]
  • Nucleosynthesis in thermonuclear supernovae by Ivo R. Seitenzahl and Dean M. Townsley [2017/04]
  • Observational Properties of Thermonuclear Supernovae by Saurabh W. Jha et al. [Nature Astronomy 3, 706 (2019)]
  • Stellar evolution, SN explosion, and nucleosynthesis by K. Maeda [2022/10]

• Aspects: REMNANTS:

• Aspects: DELAY-TIME DISTRIBUTION:
  • Type-Ia supernovae: new clues to their progenitors from the delay-time distribution by Dan Maoz [2010/07]

• Aspects: DISTANCE: Leibundgut and Sollerman 2002/04;

• Aspects: IMPOSTORS:
  • Supernova Impostors and Other Gap Transients by Andrea Pastorello and Morgan Fraser [Nature Astronomy 3, 676 (2019)]

• Aspects: INTERACTIONS:
  • Interacting Supernovae: Types IIn and Ibn by Nathan Smith [2016/12]
  • Thermal and non-thermal emission from circumstellar interaction [re: supernovae] by Roger A. Chevalier and Claes Fransson [2016/12]
  • Circumstellar interaction in supernovae in dense environments -- an observational perspective by Poonam Chandra [2017/12]
  • Interacting supernovae by L. Dessart [2024/05]

• Aspects: NEBULAR PHASE:
  • Spectra of Supernovae in the Nebular Phase by Anders Jerkstrand [2017/02]

• Aspects: PROGENITOR STARS:
  • Massive stars in their death-throes by John J. Eldridge [2008/09]
  • Type-Ia supernovae: new clues to their progenitors from the delay-time distribution by Dan Maoz [2010/07]
  • Massive Stars and their Supernovae by Friedrich-Karl Thielemann et al. [2010/08]
  • Type-Ia supernova rates and the progenitor problem, a review by Dan Maoz and Filippo Mannucci [2011/11]
  • Resolved Host Studies of Stellar Explosions by Emily M. Levesque [2016/02]
  • Progenitors of type Ia supernovae by Keiichi Maeda and Yukikatsu Terada [International Journal of Modern Physics D 25, 1630024 (2016)]
  • Stellar evolution, SN explosion, and nucleosynthesis by K. Maeda [2022/10]

• Aspects: RATES: Cappellaro and Turatto 2000/12;
  • Type-Ia supernova rates and the progenitor problem, a review by Dan Maoz and Filippo Mannucci [2011/11]

• Aspects: SHOCKWAVES: Pal 98/03;
• Aspects: SPECTRUM: GAMMA RAY: Paul et al.2001/03;

• Aspects: SPECTRUM: RADIO:
  • Radio Supernovae by Rob J. Beswick [2006/09]

• Aspects: SPECTRUM: X RAY: Immler and Lewin 2002/02;

• Aspects: SURVIVING COMPANIONS:
  • Surviving Companions of Type Ia Supernovae: Theory and Observations by Pilar Ruiz-Lapuente [2018/12]

• Processes: NUCLEOSYNTHESIS: Oberhummer et al. 96/08; Thielemann et al. 98/02; Langanke 99/01; Nomoto et al. 2002/09; Haxton 2003/01; Rauscher 2003/09;
  • Nucleosynthesis in thermonuclear supernovae by Ivo R. Seitenzahl and Dean M. Townsley [2017/04]
  • Neutrinos, supernovae, and the origin of the heavy elements by Yong-Zhong Qian [Science China: Physics, Mechanics & Astronomy 61, 049501 (2018)]
  • Synthesis of radioactive elements in novae and supernovae and their use as a diagnostic tool by J. Isern et al. [2021/01]
  • Stellar evolution, SN explosion, and nucleosynthesis by K. Maeda [2022/10]
  • The physics of core-collapse supernovae: Explosion mechanism and explosive nucleosynthesis by L. Boccioli and L. Roberti [2024/03]

• Re: ACCELERATION OF UNIVERSE: Leibundgut and Sollerman 2002/04;
  • The expansion of the universe observed with supernovae by Pierre Astier [Reports on Progress in Physics 75, 116901 (2012)]

• Re: BINARY STARS:
  • Type Ia Supernova Explosions in Binary Systems by Z.-W. Liu et al. [2023/05]

• Re: BIOLOGY:
  • Mass extinctions and supernova explosions by Gunther Korschinek [2016/09]

• Re: COSMIC RAYS: Biermann 95/01;
  • Ultra-high Energy Cosmic Rays and Neutrinos from Gamma-Ray Bursts, Hypernovae and Galactic Shocks by P. Mészáros [2014/03]
  • High Energy Cosmic Rays From Supernovae by Giovanni Morlino [2016/11]
  • Particle acceleration at shocks: An introduction by D. Caprioli [2023/07]

• Re: COSMOLOGY: Schommer et al. 99/09; Riess 2000/05; Leibundgut and Sollerman 2002/04; Ruiz-Lapuente 2003/04;
  • Foundations of Supernova Cosmology by Robert P. Kirshner [2009/10]
  • Supernova cosmology: legacy and future by Ariel Goobar, Bruno Leibundgut [2011/02]
  • The expansion of the universe observed with supernovae by Pierre Astier [Reports on Progress in Physics 75, 116901 (2012)]
  • The Dark Universe by Stefan S. Brems et al. [2017/09] Exercises and proceedings from the 2017 German-Italian WE Heraeus Summer School for teachers: supernova cosmology, virial theorem, rotation curves, CMB.

• Re: CP VIOLATION: Qian 98/02;

• Re: DARK ENERGY: Schommer et al. 99/09; Leibundgut and Sollerman 2002/04;
  • Foundations of Supernova Cosmology by Robert P. Kirshner [2009/10]
  • Supernova cosmology: legacy and future by Ariel Goobar, Bruno Leibundgut [2011/02]
  • Observational Probes of Dark Energy by Yun Wang [2012/01]

• Re: DENSITY OF UNIVERSE: Schommer et al. 99/09;

• Re: DUST:
  • Dust Production in Supernovae by Isabelle Cherchneff [2013/11]

• Re: EARLY UNIVERSE:
  • Supernovae at the cosmic dawn by Ke-Jung Chen [International Journal of Modern Physics D 23, 1430008 (2014)]

• Re: GAMMA RAY BURSTS: Wheeler 99/09; Della Valle 2005/04; Woosley and Bloom 2006/09;
  • Gamma Ray Bursts and their links with Supernovae and Cosmology by Peter Mészáros and Neil Gehrels [Research in Astronomy and Astrophysics 12, 1139 (2012)]

• Re: GRAVITATIONAL LENSING:
  • Strong Gravitational Lensing of Explosive Transients by Masamune Oguri [2019/07]

• Re: GRAVITATIONAL RADIATION:
  • Gravitational waves from core-collapse supernovae by E. Abdikamalov et al. [2020/10]

• Re: HUBBLE'S CONSTANT: Branch 98/01;

• Re: MASSIVE STARS:
  • Massive Stars and their Supernovae by Friedrich-Karl Thielemann et al. [2010/08]
  • Giant eruptions of very massive stars by Kris Davidson [2016/02]
  • Supernovae from massive stars by Marco Limongi [2017/06]

• Re: MOLECULAR CLOUDS: Chevalier 2001/02;

• Re: NEUTRINO OPACITY: Qian 98/02;

• Re: NEUTRINOS: Langanke 99/01; Haxton 99/01a; Haxton 99/01b; Balantekin and Haxton 99/03; Rajasekaran 2000/04; Cei 2002/02; Raffelt 2002/08; Choubey and Kar 2002/12;
  • Neutrino masses and mixings and... by Alessandro Strumia and Francesco Vissani [2010/04] 243 pp.
  • Neutrinos and the stars by Georg Raffelt [2011/08]
  • Ultra-high Energy Cosmic Rays and Neutrinos from Gamma-Ray Bursts, Hypernovae and Galactic Shocks by P. Mészáros [2014/03]
  • The Physics of Supernova Neutrino Oscillations by James P. Kneller [2015/07]
  • Supernova Neutrinos: Theory by Irene Tamborra [2015/12]
  • Theoretical developments in supernova neutrino physics: mass corrections and pairing correlators by Cristina Volpe [2016/01]
  • Neutrino-Driven Explosions [of Supernovae] by Hans-Thomas Janka [2017/02]
  • Neutrino Emission from Supernovae by Hans-Thomas Janka [2017/02]
  • Supernova Signatures of Neutrino Mass Ordering by Kate Scholberg [2017/07]
  • Neutrinos, supernovae, and the origin of the heavy elements by Yong-Zhong Qian [Science China: Physics, Mechanics & Astronomy 61, 049501 (2018)]
  • Introduction to Neutrino Astronomy by Andrea Gallo Rosso et al. [2018/06]
  • Supernova neutrinos: Flavour conversion mechanisms and new physics scenarios by M. Sen [2024/05]

• Re: NEUTRON STARS:
  • Neutron Stars in Supernovae and Their Remnants by Roger A. Chevalier [2010/11]
  • Neutron Star Formation and Core Collapse Supernovae by Pablo Cerdá-Durán and Nancy Elias-Rose [2018/06]

• Re: NUCLEAR PHYSICS: Qian 98/02;
  • Nuclear pasta in supernovae and neutron stars by Gentaro Watanabe and Toshiki Maruyama [2011/09]

• Re: ROTATING STARS:
  • Supernovae from rotating stars by Georges Meynet and Andre Maeder [2017/11]

• Re: TURBULENCE:
  • Turbulence in Core-Collapse Supernovae by David Radice et al. [2017/10]

THE NET ADVANCE OF PHYSICS