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The Three Dimensional Evolution to Core Collapse of a Massive Star

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arxiv 1503.02199 v2 pith:T5K2LRFR submitted 2015-03-07 astro-ph.HE astro-ph.SR

The Three Dimensional Evolution to Core Collapse of a Massive Star

classification astro-ph.HE astro-ph.SR
keywords corecollapseironburningcaptureconvectiondimensionaldriven
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We present the first three dimensional (3D) simulation of the final minutes of iron core growth in a massive star, up to and including the point of core gravitational instability and collapse. We self-consistently capture the development of strong convection driven by violent Si burning in the shell surrounding the iron core. This convective burning builds the iron core to its critical (Chandrasekhar) mass and collapse ensues, driven by electron capture and photodisintegration. The non-spherical structure and motion (turbulent fluctuations) generated by 3D convection is substantial at the point of collapse. We examine the impact of such physically-realistic 3D initial conditions on the core-collapse supernova mechanism using 3D simulations including multispecies neutrino leakage. We conclude that non-spherical progenitor structure should not be ignored, and has a significant and favorable impact on the likelihood for neutrino-driven explosions.

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Cited by 2 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Building three-dimensional giant stellar models for common envelope simulations

    astro-ph.SR 2026-06 unverdicted novelty 5.0

    Depositing stellar luminosity in an inner shell and cooling low-density outer cells produces a stable pulsating 3D red supergiant model for common envelope simulations without relaxation.

  2. Parameter Estimation Horizon of Core-Collapse Supernovae with Current and Next-Generation Gravitational-Wave Detectors

    astro-ph.HE 2026-05 unverdicted novelty 5.0

    Machine learning extracts core rotation and signal properties from CCSN gravitational waves, with next-generation detectors constraining rotation beyond 100 kpc for favorable orientations despite some uncertainties.