Core‐Collapse Very Massive Stars: Evolution, Explosion, and Nucleosynthesis of Population III 500–1000M⊙Stars

AbstractWe calculate evolution, collapse, explosion, and nucleosynthesis of Population III very massive stars with 500 M⊙ and 1000 M⊙. It was found that both 500 M⊙ and 1000 M⊙ models enter the region of pair-instability but continue to undergo core collapse to black holes. For moderately aspherical explosions, the patterns of nucleosynthesis match the observational data of intergalactic and intercluster medium and hot gases in M82, better than models involving hypernovae and pair instability supernovae.Our results suggest that explosions of Population III core-collapse very massive stars contribute significantly to the chemical evolution of gases in clusters of galaxies. The final black hole masses are about 500 M⊙ for our most massive 1000 M⊙ models. This result may support the view that Population III very massive stars are responsible for the origin of intermediate mass black holes which were recently reported to be discovered.

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Gravitational Collapse and Neutrino Emission of Population III Massive Stars

Journal of Physics Conference Series ◽

10.1088/1742-6596/31/1/055 ◽

2006 ◽

Vol 31 ◽

pp. 205-206

Author(s):

Ken'ichiro Nakazato ◽

Kohsuke Sumiyoshi ◽

Shoichi Yamada

Keyword(s):

Gravitational Collapse ◽

Massive Stars ◽

Neutrino Emission ◽

Population Iii

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Neutrino emission from the collapse of ∼104 M⊙ Population III supermassive stars

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stab2592 ◽

2021 ◽

Vol 508 (1) ◽

pp. 828-841

Author(s):

Chris Nagele ◽

Hideyuki Umeda ◽

Koh Takahashi ◽

Takashi Yoshida ◽

Kohsuke Sumiyoshi

Keyword(s):

Dark Matter ◽

Massive Star ◽

Direct Detection ◽

Mass Range ◽

Core Collapse ◽

Low Density ◽

Large Radius ◽

Neutrino Luminosity ◽

Neutrino Background ◽

Population Iii

ABSTRACT We calculate the neutrino signal from Population III supermassive star (SMS) collapse using a neutrino transfer code originally developed for core-collapse supernovae and massive star collapse. Using this code, we are able to investigate the SMS mass range thought to undergo neutrino trapping (∼104 M⊙), a mass range which has been neglected by previous works because of the difficulty of neutrino transfer. For models in this mass range, we observe a neutrino sphere with a large radius and low density compared to typical massive star neutrino spheres. We calculate the neutrino light curve emitted from this neutrino sphere. The resulting neutrino luminosity is significantly lower than the results of a previous analytical model. We briefly discuss the possibility of detecting a neutrino burst from an SMS or the neutrino background from many SMSs and conclude that the former is unlikely with current technology, unless the SMS collapse is located as close as 1 Mpc, while the latter is also unlikely even under very generous assumptions. However, the SMS neutrino background is still of interest as it may serve as a source of noise in proposed dark matter direct detection experiments.

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A shallow water analogue of asymmetric core-collapse, and neutron star kick/spin

Proceedings of the International Astronomical Union ◽

10.1017/s1743921312012811 ◽

2011 ◽

Vol 7 (S279) ◽

pp. 134-137

Author(s):

Thierry Foglizzo ◽

Frédéric Masset ◽

Jérôme Guilet ◽

Gilles Durand

Keyword(s):

Neutron Star ◽

Shallow Water ◽

Acoustic Waves ◽

Large Scale ◽

Massive Stars ◽

Core Collapse ◽

Hydraulic Jumps ◽

Core Collapse Supernova ◽

Accretion Shock

AbstractMassive stars end their life with the gravitational collapse of their core and the formation of a neutron star. Their explosion as a supernova depends on the revival of a spherical accretion shock, located in the inner 200km and stalled during a few hundred milliseconds. Numerical simulations suggest that the large scale asymmetry of the neutrino-driven explosion is induced by a hydrodynamical instability named SASI. Its non radial character is able to influence the kick and the spin of the resulting neutron star. The SWASI experiment is a simple shallow water analog of SASI, where the role of acoustic waves and shocks is played by surface waves and hydraulic jumps. Distances in the experiment are scaled down by a factor one million, and time is slower by a factor one hundred. This experiment is designed to illustrate the asymmetric nature of core-collapse supernova.

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Lithium, beryllium, and boron production in core-collapse supernovae

Proceedings of the International Astronomical Union ◽

10.1017/s1743921310004631 ◽

2009 ◽

Vol 5 (S268) ◽

pp. 463-468

Author(s):

Ko Nakamura ◽

Takashi Yoshida ◽

Toshikazu Shigeyama ◽

Toshitaka Kajino

Keyword(s):

Massive Star ◽

Massive Stars ◽

Circumstellar Matter ◽

High Energy ◽

Core Collapse ◽

Light Elements ◽

Speed Of Light ◽

Large Numbers ◽

Very High Energy ◽

Very High

AbstractType Ic supernova (SN Ic) is the gravitational collapse of a massive star without H and He layers. It propels several solar masses of material to the typical velocity of 10,000 km/s, a very small fraction of the ejecta nearly to the speed of light. We investigate SNe Ic as production sites for the light elements Li, Be, and B, via the neutrino-process and spallations. As massive stars collapse, neutrinos are emitted in large numbers from the central remnants. Some of the neutrinos interact with nuclei in the exploding materials and mainly 7Li and 11B are produced. Subsequently, the ejected materials with very high energy impinge on the interstellar/circumstellar matter and spall into light elements. We find that the ν-process in the current SN Ic model produces a significant amount of 11B, consistent with observations if combined with B isotopes from the following spallation production.

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Nucleosynthesis in Asymmetric, Core-Collapse Supernovae of Massive Stars

Proceedings of the 14th International Symposium on Nuclei in the Cosmos (NIC2016) ◽

10.7566/jpscp.14.020621 ◽

2017 ◽

Author(s):

Shin-ichiro Fujimoto ◽

Masaomi Ono ◽

Masa-aki Hashimoto ◽

Kei Kotake

Keyword(s):

Massive Stars ◽

Core Collapse

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The SuperN-Project: Porting and Optimizing VERTEX-PROMETHEUS on the Cray XE6 at HLRS for Three-Dimensional Simulations of Core-Collapse Supernova Explosions of Massive Stars

High Performance Computing in Science and Engineering ‘12 ◽

10.1007/978-3-642-33374-3_8 ◽

2012 ◽

pp. 81-93

Author(s):

F. Hanke ◽

A. Marek ◽

B. Müller ◽

H.-Th. Janka

Keyword(s):

Massive Stars ◽

Three Dimensional ◽

Core Collapse ◽

Core Collapse Supernova ◽

Supernova Explosions ◽

Three Dimensional Simulations

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Modeling the early-time spectra of core-collapse supernovae

Proceedings of the International Astronomical Union ◽

10.1017/s1743921316004956 ◽

2015 ◽

Vol 11 (A29B) ◽

pp. 213-214

Author(s):

Jose H. Groh

Keyword(s):

Shock Front ◽

Recent Progress ◽

Massive Stars ◽

Spatial Scales ◽

Early Time ◽

Front Velocity ◽

Core Collapse ◽

Major Significance ◽

Observational Techniques ◽

Early Phases

Core-collapse supernovae (SNe) are the final act in the evolution of stars more massive than about 8–9 solar masses. Determining the progenitors of these explosive events and how massive stars are linked to the different SN types are topics of major significance for several fields of astrophysics. Recent progress in observational techniques now allow for rapid-response spectroscopic observations of SNe within a day of detection Gal-Yam et al. (2014). This allows the study of early phases when the SN shock front has not yet reached spatial scales of 1014 cm. Depending on the progenitor's wind density and SN shock front velocity, these early-time SN observations may probe epochs early enough that the dense parts of the progenitor wind and circumstellar medium (CSM) have not yet been overrun by the SN shock front.

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Angular momentum transport in massive stars and natal neutron star rotation rates

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stz2009 ◽

2019 ◽

Vol 488 (3) ◽

pp. 4338-4355 ◽

Cited By ~ 7

Author(s):

Linhao Ma ◽

Jim Fuller

Keyword(s):

Angular Momentum ◽

Massive Stars ◽

Baroclinic Instability ◽

Core Collapse ◽

Slow Rotation ◽

Low Mass Stars ◽

Rotation Rates ◽

Rotation Periods ◽

Low Mass ◽

Binary Evolution

Abstract The internal rotational dynamics of massive stars are poorly understood. If angular momentum (AM) transport between the core and the envelope is inefficient, the large core AM upon core-collapse will produce rapidly rotating neutron stars (NSs). However, observations of low-mass stars suggest an efficient AM transport mechanism is at work, which could drastically reduce NS spin rates. Here, we study the effects of the baroclinic instability and the magnetic Tayler instability in differentially rotating radiative zones. Although the baroclinic instability may occur, the Tayler instability is likely to be more effective for AM transport. We implement Tayler torques as prescribed by Fuller, Piro, and Jermyn into models of massive stars, finding they remove the vast majority of the core’s AM as it contracts between the main-sequence and helium-burning phases of evolution. If core AM is conserved during core-collapse, we predict natal NS rotation periods of $P_{\rm NS} \approx 50\!-\!200 \, {\rm ms}$, suggesting these torques help explain the relatively slow rotation rates of most young NSs, and the rarity of rapidly rotating engine-driven supernovae. Stochastic spin-up via waves just before core-collapse, asymmetric explosions, and various binary evolution scenarios may increase the initial rotation rates of many NSs.

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