Formation of Close-in Neptunes Around Low-Mass Stars Through Breaking Resonant Chains

arXiv - PHYS - Earth and Planetary Astrophysics Pub Date : 2024-09-09 DOI:arxiv-2409.05748

Donald Liveoak, Sarah Millholland

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Abstract

Conventional planet formation theories predict a paucity of massive planets around small stars, especially very low-mass ($0.1 - 0.3 \ M_{\odot}$) mid-to-late M dwarfs. Such tiny stars are expected to form planets of terrestrial sizes, but not much bigger. However, this expectation is challenged by the recent discovery of LHS 3154 b, a planet with period of 3.7 days and minimum mass of $13.2 \ M_{\oplus}$ orbiting a $0.11 \ M_{\odot}$ star. Here, we propose that close-in Neptune-mass planets like LHS 3154 b formed through an anomalous series of mergers from a primordial compact system of super-Earths. We perform simulations within the context of the "breaking the chains" scenario, in which super-Earths initially form in tightly-spaced chains of mean-motion resonances before experiencing dynamical instabilities and collisions. Planets as massive and close-in as LHS 3154 b ($M_p \sim 12 - 20 \ M_{\oplus}$, $P < 7$ days) are produced in $\sim$1% of simulated systems, in broad agreement with their low observed occurrence. These results suggest that such planets do not require particularly unusual formation conditions but rather are an occasional byproduct of a process that is already theorized to explain compact multi-planet systems. Interestingly, our simulated systems with LHS 3154 b-like planets also contain smaller planets at around $\sim 30$ days, offering a possible test of this hypothesis.

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通过打破共振链在低质量恒星周围形成近邻海王星

传统的行星形成理论预言，小恒星，特别是质量很低（0.1 - 0.3 （M_{\odot}$）的中晚期M矮星周围很少有大质量行星。这种小恒星预计会形成类似地球大小的行星，但不会大很多。然而，最近发现的LHS 3154 b对这一预期提出了挑战，这颗行星的周期为3.7天，最小质量为13.2 M_{\oplus}$，围绕着一颗0.11 M_{\odot}$的恒星运行。在这里，我们提出，像LHS 3154 b这样质量接近海王星的行星是通过一系列异常的合并形成的，这些合并来自一个由超级地球组成的原始紧凑系统。我们在 "打破链条 "的情景下进行了模拟，在这种情景下，超级地球最初是在经历动力学不稳定性和碰撞之前，在平均运动共振的紧密间隔链条中形成的。像LHS 3154 b（$M_p \sim 12 - 20 \M_{\oplus}$，$P < 7$天）这样大质量和近距离的行星只在$\sim$1%的模拟系统中产生，这与它们的低观测发生率大体一致。这些结果表明，这类行星并不需要特别不寻常的形成条件，而只是一个偶然的副产品，这个过程已经被理论化来解释紧凑的多行星系统了。有趣的是，我们模拟的具有类似LHS 3154 b行星的系统中也包含了大约$\sim 30$天的较小行星，这为检验这一假说提供了可能。

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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arXiv - PHYS - Earth and Planetary Astrophysics

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