Systematic features of axisymmetric neutrino-driven core-collapse supernova models in multiple progenitors

Nakamura, Ko; Takiwaki, Tomoya; Kuroda, T.; Kotake, Kei

doi:10.1093/pasj/psv073

Cited by 124 publications

(101 citation statements)

References 66 publications

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“…Hence a careful observational estimate of the true distribution of explosion energies is now required for a quantitative compari son. In line with longtime 2D simulations (Nakamura et al 2015, Bruenn et al 2016, they also find a weak trend for more mas sive progenitors to explode more energeti cally, which appears to be compatible with observations (Poznanski 2013).…”

Section: The Explosion Landscapesupporting

confidence: 82%

“…3D simula tion can make firm predictions only for progenitors at the lowmass end, where Melson et al (2015b) pre dict an explosion energy of ~10 50 erg for a 9.6 M ⊙ pro genitor. Selfconsistent 2D simulations can be taken well beyond the first second (Mül ler 2015, Bruenn et al 2016) and are cheap enough to scan a wide range of progeni tor models (Nakamura 2015), but cannot be trusted to predict the energetics of the explosion correctly (Müller 2015).…”

Section: Multidimensional Modelsmentioning

confidence: 99%

See 1 more Smart Citation

How to blow up a massive star

Müller

Smartt

2017

Astronomy &Amp; Geophysics

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Section: The Explosion Landscapesupporting

confidence: 82%

Section: Multidimensional Modelsmentioning

confidence: 99%

How to blow up a massive star

Müller

Smartt

2017

Astronomy &Amp; Geophysics

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“…Except for the least massive supernova progenitors (Kitaura et al 2006;Müller et al 2012b), successful first-principle simulations of supernova explosions (Buras et al 2006;Marek & Janka 2009;Müller et al 2012aMüller et al ,b, 2013Janka et al 2012;Bruenn et al 2013Bruenn et al , 2016Suwa et al 2010;Nakamura et al 2015;Takiwaki et al 2012Takiwaki et al , 2014Summa et al 2015;O'Connor & Couch 2015) consistently show the persistence of accretion downflows for many hundreds of milliseconds after shock revival -and in many cases to the very end of the simulations so that the final explosion parameters of the models cannot be determined yet. A more quantitative analysis of the mass fluxesṀ out andṀ acc in neutrinodriven outflows and cold accretion downflows in the long-time simulations of Müller (2015) revealed that the accretion through downflows completely outweighs the outflow rate for a long time,…”

Section: Accretion After Shock Revivalmentioning

confidence: 99%

A simple approach to the supernova progenitor–explosion connection

Müller

Heger

Liptai

et al. 2016

Mon. Not. R. Astron. Soc.

192

372

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We present a new approach to understand the landscape of supernova explosion energies, ejected nickel masses, and neutron star birth masses. In contrast to other recent parametric approaches, our model predicts the properties of neutrino-driven explosions based on the precollapse stellar structure without the need for hydrodynamic simulations. The model is based on physically motivated scaling laws and simple differential equations describing the shock propagation, the contraction of the neutron star, the neutrino emission, the heating conditions, and the explosion energetics. Using model parameters compatible with multi-D simulations and a fine grid of thousands of supernova progenitors, we obtain a variegated landscape of neutron star and black hole formation similar to other parameterised approaches and find good agreement with semi-empirical measures for the "explodability" of massive stars. Our predicted explosion properties largely conform to observed correlations between the nickel mass and explosion energy. Accounting for the coexistence of outflows and downflows during the explosion phase, we naturally obtain a positive correlation between explosion energy and ejecta mass. These correlations are relatively robust against parameter variations, but our results suggest that there is considerable leeway in parametric models to widen or narrow the mass ranges for black hole and neutron star formation and to scale explosion energies up or down. Our model is currently limited to an all-or-nothing treatment of fallback and there remain some minor discrepancies between model predictions and observational constraints.

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“…This behavior is the reverse of what might be expected if low compactness signaled greater explodability. Finally, the work of Nakamura et al (2015) suggests that though they see a weak correlation, it is not monotonic with compactness. In fact, many of their plots versus compactness resemble scatter plots.…”

Section: Compactnessmentioning

confidence: 99%

Crucial Physical Dependencies of the Core-Collapse Supernova Mechanism

et al. 2018

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We explore with self-consistent 2D FORNAX simulations the dependence of the outcome of collapse on many-body corrections to neutrino-nucleon cross sections, the nucleon-nucleon bremsstrahlung rate, electron capture on heavy nuclei, pre-collapse seed perturbations, and inelastic neutrino-electron and neutrino-nucleon scattering. Importantly, proximity to criticality amplifies the role of even small changes in the neutrino-matter couplings, and such changes can together add to produce outsized effects. When close to the critical condition the cumulative result of a few small effects (including seeds) that individually have only modest consequence can convert an anemic into a robust explosion, or even a dud into a blast. Such sensitivity is not seen in one dimension and may explain the apparent heterogeneity in the outcomes of detailed simulations performed internationally. A natural conclusion is that the different groups collectively are closer to a realistic understanding of the mechanism of core-collapse supernovae than might have seemed apparent. Supernovae Edited by

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Systematic features of axisymmetric neutrino-driven core-collapse supernova models in multiple progenitors

Cited by 124 publications

References 66 publications

How to blow up a massive star

How to blow up a massive star

A simple approach to the supernova progenitor–explosion connection

Crucial Physical Dependencies of the Core-Collapse Supernova Mechanism

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