The Development of Explosions in Axisymmetric Ab Initio Core-Collapse Supernova Simulations of 12–25 
    Stars

Bruenn, Stephen W.; Lentz, Eric J.; Hix, W. R.; Mezzacappa, Anthony; Harris, J. Austin; Messer, O. E. Bronson; Endeve, Eirik; Blondin, John M.; Chertkow, Merek A.; Lingerfelt, Eric J.; Marronetti, Pedro; Yakunin, Konstantin N.

doi:10.3847/0004-637x/818/2/123

Cited by 204 publications

(316 citation statements)

References 188 publications

(291 reference statements)

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“…Since the neutrino power deposition goes approximately as the product of this depth and the luminosities, high-compactness progenitors have an advantage. Therefore, it is feasible that more massive models might be more explosive, and this trend has been seen by other modelers (Summa et al , 2018Bruenn et al 2016). In fact, in the Summa et al and Bruenn et al papers for the Woosley and Heger (2007) models, the postbounce explosion times increase in the sequence 20, 25, 15, and 12 M , which is clearly not monotonic with compactness.…”

Section: Compactnessmentioning

confidence: 94%

“…To the point, Skinner et al (2016) have shown that the ray-by-ray anomalies in the angular distribution of the radiation field and corresponding neutrino heating rates can reinforce the axial sloshing motions in 2D and push the shock into explosion. 1 Bruenn et al (2013Bruenn et al ( , 2016 find explosions in 2D (axially symmetry) for all the progenitors they studied (the 12-, 15-, 20-, and 25-M models of Woosley and Heger 2007), but the models all explode at about the same post-bounce time (∼100 milliseconds) and the shock radii never decrease in value. When performed in 3D for the 15-M model of Woosley and Heger (2007), Lentz et al (2015) obtain a weaker explosion delayed in its onset by an extra ∼100 milliseconds.…”

Section: Introductionmentioning

confidence: 93%

“…In fact, the numerical algorithms, resolutions, and input physics all differ, and even when the physics is deemed similar, the implementations and approximations surely differ. The ORNL group (Bruenn et al 2013(Bruenn et al , 2016, with their CHIMERA code, uses multi-group flux-limited diffusion (MGFLD) neutrino transport (Bruenn 1985), the VH-1 Newtonian hydrodynamics package, a monopole correction for general relativity (GR) (Marek et al 2006), but multiple one-dimensional solves for multi-dimensional transport using the so-called "ray-by-ray+" approach (Buras et al 2003;Burrows et al 1995). Such a dimensional reduction for the transport, particularly manifest in 2D, ignores lateral, non-radial radiative transport, which has been shown to be of quantitative (Ott et al 2008;Brandt et al 2011;Burrows 2013;Dolence et al 2015;Sumiyoshi et al 2015) and qualitative (Skinner et al 2016) importance.…”

Section: Introductionmentioning

confidence: 99%

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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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Section: Compactnessmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

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Crucial Physical Dependencies of the Core-Collapse Supernova Mechanism

et al. 2018

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“…Detailed spherically symmetric one-dimensional (1D) simulations do not explode (Liebendörfer et al 2001), except when particular low-mass progenitor models are used (e.g., Fischer et al 2010;Hüdepohl et al 2010). Multiple simulations including energydependent (multi-group) neutrino transport and imposing axial symmetry (2D) do exhibit explosions (Müller et al 2012b(Müller et al , 2012aBruenn et al 2013Bruenn et al , 2016, although some do not . Interestingly, the first simulations including ray-by-ray neutrino transport 11 without symmetries imposed three-dimensionally on the hydrodynamics did not find explosions in models that exploded when axisymmetry was assumed (Hanke et al 2013).…”

Section: Introductionmentioning

confidence: 99%

General-Relativistic Three-Dimensional Multi-Group Neutrino Radiation-Hydrodynamics Simulations of Core-Collapse Supernovae

Roberts

Ott

Haas

et al. 2016

ApJ

188

182

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We report on a set of long-term general-relativistic three-dimensional (3D) multi-group (energy-dependent) neutrino radiation-hydrodynamics simulations of core-collapse supernovae. We employ a full 3D two-moment scheme with the local M1 closure, three neutrino species, and 12 energy groups per species. With this, we follow the post-core-bounce evolution of the core of a nonrotating - M 27 progenitor in full unconstrained 3D and in octant symmetry for 380 ms. We find the development of an asymmetric runaway explosion in our unconstrained simulation. We test the resolution dependence of our results and, in agreement with previous work, find that low resolution artificially aids explosion and leads to an earlier runaway expansion of the shock. At low resolution, the octant and full 3D dynamics are qualitatively very similar, but at high resolution, only the full 3D simulation exhibits the onset of explosion.

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“…The delayed neutrino mechanism (e.g., Bruenn et al 2016;Janka et al 2016;Müller 2016;Burrows et al 2017), although the most popular in the literature, encounters problems (e.g., Papish et al 2015;Kushnir 2015b). An alternative mechanism to account for all CCSNe is the jet feedback mechanism (JFM; for a review see .…”

Section: Introductionmentioning

confidence: 99%

The two promising scenarios to explode core collapse supernovae

Soker

2017

Res. Astron. Astrophys.

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I compare to each other what I consider to be the two most promising scenarios to explode core-collapse supernovae (CCSNe). Both are based on the negative jet feedback mechanism (JFM). In the jittering jets scenario a collapsing core of a single slowly-rotating star can launch jets. The accretion disk or belt (a sub-Keplerian accretion flow concentrated toward the equatorial plane) that launches the jets is intermittent with varying directions of the axis. Instabilities, such as the standing accretion shock instability (SASI), lead to stochastic angular momentum variations that allow the formation of the intermittent accretion disk/belt. According to this scenario no failed CCSNe exist. According to the fixed axis scenario, the core of the progenitor star must be spun up during its late evolutionary phases, and hence all CCSNe are descendants of strongly interacting binary systems, most likely through a common envelope evolution (whether the companion survives or not). Due to the strong binary interaction, the axis of the accretion disk that is formed around the newly born neutron star has a more or less fixed direction. According to the fixed axis scenario, accretion disk/belt are not formed around the newly born neutron star of single stars; they rather end in failed CCSNe. I also raise the possibility that the jittering jets scenario operates for progenitors with initial mass of 8M ⊙ M ZAMS 18M ⊙ , while the fixed axis scenario operates for M ZAMS 18M ⊙ . For the first time these two scenarios are compared to each other, as well as to some aspects of neutrino-driven explosion mechanism. These new comparisons further suggest that the JFM plays a major role in exploding massive stars.

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The Development of Explosions in Axisymmetric Ab Initio Core-Collapse Supernova Simulations of 12–25 Stars

Cited by 204 publications

References 188 publications

Crucial Physical Dependencies of the Core-Collapse Supernova Mechanism

Crucial Physical Dependencies of the Core-Collapse Supernova Mechanism

General-Relativistic Three-Dimensional Multi-Group Neutrino Radiation-Hydrodynamics Simulations of Core-Collapse Supernovae

The two promising scenarios to explode core collapse supernovae

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