SN 2023ixf: An average-energy explosion with circumstellar medium and a precursor

IF 5.8 2区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Astronomy & Astrophysics Pub Date : 2025-02-24 DOI:10.1051/0004-6361/202452758

Alexandra Kozyreva, Andrea Caputo, Petr Baklanov, Alexey Mironov, Hans-Thomas Janka

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引用次数: 0

Abstract

The fortunate proximity of the Type II supernova (SN) 2023ixf has allowed astronomers to follow its evolution from almost the moment of the collapse of the progenitor’s core. SN 2023ixf can be explained as an explosion of a massive star with an energy of 0.7 × 10^{51^{erg but with a greatly reduced envelope mass, probably because of binary interaction. In our radiative-transfer simulations, the SN ejecta of 6 M_{⊙_{interact with circumstellar matter (CSM) of (0.55–0.83) M_{⊙_{extending to 10^{15^{cm, which results in a light curve (LC) peak matching that of SN 2023ixf. The origin of this required CSM might be gravity waves originating from convective shell burning, which could enhance wind-like mass loss during the late stages of stellar evolution. The steeply rising low-luminosity flux during the first hours after observationally confirmed non-detection, however, cannot be explained by the collision of the energetic SN shock with the CSM. Instead, we consider it as a precursor that we can fit by the emission from (0.5–0.9) M_{⊙_{of matter that was ejected with an energy of ∼10^{49^{erg a fraction of a day before the main shock of the SN explosion reached the surface of the progenitor. The source of this energy injection into the outermost shell of the stellar envelope could also be dynamical processes related to the convective activity in the progenitor’s interior or envelope. Alternatively, the early rise of the LC could point to the initial breakout of a highly non-spherical SN shock or of fast-moving asymmetrically ejected matter that was swept out well ahead of the SN shock, potentially in a low-energy, nearly relativistic jet. We also discuss that pre-SN outbursts and LC precursors can be used to study or to constrain energy deposition in the outermost stellar layers by the decay of exotic particles, such as axions, which could be produced simultaneously with neutrinos in the newly formed hot neutron star. A careful analysis of the earliest few hours of the LCs of SNe can reveal elusive precursors and provide a unique window onto the surface activity of massive stars during their core collapse. This can greatly improve our understanding of stellar physics and consequently also offer new tools for searching for exotic particles.}}}}}}}}}}}}

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SN 2023ixf：具有星周介质和前体的平均能量爆炸

幸运的是，II型超新星（SN） 2023ixf的接近使天文学家能够从其祖先的核心坍塌的那一刻开始追踪它的演化。SN 2023ixf可以解释为一颗能量为0.7 × 1051 erg的大质量恒星的爆炸，但包络质量大大减少，可能是因为双星相互作用。在我们的辐射传输模拟中，6 M⊙的SN抛射物与（0.55 ~ 0.83）M⊙的星周物质（CSM）相互作用延伸至1015 cm，产生了与SN 2023ixf相匹配的光曲线（LC）峰。这种必需的CSM的起源可能是来自对流壳燃烧的重力波，这可能会在恒星演化的后期阶段增加风状的质量损失。然而，在观测证实未探测后的最初几个小时内，低光度通量急剧上升，不能用高能SN激波与CSM的碰撞来解释。相反，我们认为它是一个前体，我们可以通过（0.5-0.9）M⊙的物质发射来拟合，这些物质在SN爆炸的主激波到达前体表面之前不到一天的时间里以~ 1049 erg的能量喷射出来。这种能量注入到恒星包层最外层的来源也可能是与祖恒星内部或包层的对流活动有关的动力学过程。另一种可能是，LC的早期崛起可能指向一个高度非球形的SN激波的最初爆发，或者是快速移动的非对称抛射物质，这些物质在SN激波之前被横扫出去，可能是以低能的、近乎相对论的射流形式出现的。我们还讨论了前sn爆发和LC前体可以用来研究或限制外来粒子（如轴子）的衰变在最外层的能量沉积，这些粒子可以在新形成的热中子星中与中微子同时产生。仔细分析SNe最初几个小时的lc可以揭示难以捉摸的前体，并提供一个独特的窗口来了解大质量恒星在核心坍缩期间的表面活动。这可以大大提高我们对恒星物理的理解，因此也为寻找外来粒子提供了新的工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Astronomy & Astrophysics 地学天文-天文与天体物理

CiteScore

10.20

自引率

27.70%

发文量

2105

审稿时长

1-2 weeks

期刊介绍： Astronomy & Astrophysics is an international Journal that publishes papers on all aspects of astronomy and astrophysics (theoretical, observational, and instrumental) independently of the techniques used to obtain the results.