An Integral Condition for Core-Collapse Supernova Explosions
Abstract
We derive an integral condition for core-collapse supernova (CCSN) explosions and use it to construct a new diagnostic of explodability. The fundamental challenge in CCSN theory is to explain how a stalled accretion shock revives to explode a star. In this manuscript, we assume that the shock revival is initiated by the delayed-neutrino mechanism and derive an integral condition for spherically symmetric shock expansion, . One of the most useful one-dimensional explosion conditions is the neutrino luminosity and mass-accretion rate () critical curve. Below this curve, steady-state stalled solutions exist, but above this curve, there are no stalled solutions. Burrows & Goshy suggested that the solutions above this curve are dynamic and explosive. In this manuscript, we take one step closer to proving this supposition; we show that all steady solutions above this curve have . Assuming that these steady solutions correspond to explosion, we present a new dimensionless integral condition for explosion, . roughly describes the balance between pressure and gravity, and we show that this parameter is equivalent to the condition used to infer the critical curve. The illuminating difference is that there is a direct relationship between and . Below the critical curve, may be negative, positive, and zero, which corresponds to receding, expanding, and stalled-shock solutions. At the critical curve, the minimum solution is zero; above the critical curve, , and all steady solutions have . Using one-dimensional simulations, we confirm our primary assumptions and verify that is a reliable and accurate explosion diagnostic.
Keywords
Cite
@article{arxiv.1507.08314,
title = {An Integral Condition for Core-Collapse Supernova Explosions},
author = {Jeremiah W. Murphy and Joshua C. Dolence},
journal= {arXiv preprint arXiv:1507.08314},
year = {2017}
}
Comments
18 pages and 12 figures; published in ApJ. Figures 8 & 9 and equation 21 show the main results