The Stellar Initial Mass Function of Early Dark Matter–free Gas Objects

The Astrophysical Journal Letters Pub Date : 2025-05-13 DOI:10.3847/2041-8213/add347

William Lake, Michael Y. Grudić, Smadar Naoz, Naoki Yoshida, Claire E. Williams, Blakesley Burkhart, Federico Marinacci, Mark Vogelsberger and Avi Chen

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Abstract

Among the remarkable strides made by JWST is the discovery of the earliest star clusters found to date. These have been proposed as early progenitors of globular clusters, which are known to come from the early stages of star formation in the Universe. This is an exciting development in modern astronomy, as it offers an opportunity to connect theoretical models of globular cluster formation to actual observations of these high-redshift structures. In this work, we aim to develop observational signatures of a star cluster formation route known as supersonically induced gas objects, which are dark matter–less gas clouds in the early Universe proposed as a potential origin of some globular clusters. For the first time, we follow the star formation process of these early Universe objects using high-resolution hydrodynamical simulations, including mechanical feedback. Our results suggest that the first dark matter–less star clusters are top heavy, meaning that they have a flatter initial mass function slope compared to very young low-metallicity star clusters in the local Universe, and they also have extremely high stellar mass surface densities compared to their local counterparts.

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早期无暗物质气体天体的恒星初始质量函数

在JWST取得的显著进展中，发现了迄今为止发现的最早的星团。它们被认为是球状星团的早期祖先，球状星团来自宇宙中恒星形成的早期阶段。这是现代天文学中一项令人兴奋的发展，因为它提供了将球状星团形成的理论模型与这些高红移结构的实际观测联系起来的机会。在这项工作中，我们的目标是开发被称为超音速诱导气体物体的星团形成路线的观测特征，这些天体是早期宇宙中无暗物质的气体云，被认为是一些球状星团的潜在起源。我们首次使用高分辨率流体动力学模拟（包括机械反馈）跟踪这些早期宇宙物体的恒星形成过程。我们的研究结果表明，第一批无暗物质的星团是顶重的，这意味着与当地宇宙中非常年轻的低金属丰度星团相比，它们具有更平坦的初始质量函数斜率，并且与当地同类星团相比，它们也具有极高的恒星质量表面密度。

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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The Astrophysical Journal Letters

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