Effects of stellar feedback on cores in STARFORGE

arXiv - PHYS - Astrophysics of Galaxies Pub Date : 2024-09-09 DOI:arxiv-2409.05949

K. R. Neralwar, D. Colombo, S. Offner, F. Wyrowski, K. M. Menten, A. Karska, M Y. Grudić, S. Neupane

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Abstract

Stars form in dense cores within molecular clouds and newly formed stars influence their natal environments. How stellar feedback impacts core properties and evolution is subject to extensive investigation. We performed a hierarchical clustering (dendrogram) analysis of a STARFORGE simulation modelling a giant molecular cloud to identify gas overdensities (cores) and study changes in their radius, mass, velocity dispersion, and virial parameter with respect to stellar feedback. We binned these cores on the basis of the fraction of gas affected by protostellar outflows, stellar winds, and supernovae and analysed the property distributions for each feedback bin. We find that cores that experience more feedback influence are smaller. Feedback notably enhances the velocity dispersion and virial parameter of the cores, more so than it reduces their radius. This is also evident in the linewidth-size relation, where cores in higher feedback bins exhibit higher velocities than their similarly sized pristine counterparts. We conclude that stellar feedback mechanisms, which impart momentum to the molecular cloud, simultaneously compress and disperse the dense molecular gas.

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恒星反馈对 STARFORGE 核心的影响

恒星在分子云内的致密核心中形成，新形成的恒星会影响其原生环境。恒星的反馈如何影响内核的性质和演化，还需要进行广泛的研究。我们对模拟巨型分子云的 STARFORGE 仿真进行了层次聚类（树枝图）分析，以识别气体过密（核心），并研究它们的半径、质量、速度弥散和维拉参数随恒星反馈的变化。我们根据受到原恒星外流、恒星风和超新星影响的气体比例对这些核心进行了分类，并分析了每个反馈分区的性质分布。我们发现，受到反馈影响较多的星核较小。反馈显著增强了星核的速度弥散和病毒参数，而不是减小了它们的半径。这一点在线宽-尺寸关系中也很明显，反馈较多的星核比尺寸相似的原始星核表现出更高的速度。我们的结论是，恒星反馈机制向分子云传递动量的同时，也压缩和分散了致密的分子气体。

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 - Astrophysics of Galaxies

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