Neutron Star–Dark Matter Admixed Objects in the Mass Gap Region

Particles Pub Date : 2024-08-08 DOI:10.3390/particles7030040

Michael Vikiaris

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Abstract

To this day, the nature of dark matter (DM) remains elusive despite all our efforts. This type of matter has not been directly observed, so we infer its gravitational effect. Since galaxies and supermassive objects like these are most likely to contain DM, we assume that dense objects such as neutron stars (NSs) are also likely to host DM. The NS is considered the best natural laboratory for testing theories and collecting observational data. We mainly focus on two types of DM particles, fermions and bosons, with a mass range of [0.01–1.5] GeV and repulsive interactions of about [10−4–10−1] MeV−1. Using a two-fluid model to solve the TOV equations, we find stable configurations that span hundreds of kilometers and weigh tens or even hundreds of solar masses. To visualize results, we think of a giant invisible compact DM object and the NS in the center as the core, the only visible part. Stability criteria are met for these configurations, so collapsing into a black hole is unlikely. We go further and use this work for smaller formations that exist inside the mysterious Mass Gap. We also find stable configurations of 3–4 solar masses, with NS-DM mixing capable of describing the mass gap. Regardless, the present theoretical prediction, if combined with corresponding observations, could shed light on the existence of DM and even more on its fundamental properties.

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质量差距区域的中子星-暗物质混合天体

时至今日，尽管我们做出了种种努力，但暗物质（DM）的本质仍然难以捉摸。这类物质尚未被直接观测到，因此我们推断其引力效应。由于星系和超大质量天体最有可能包含暗物质，我们假设中子星（NS）等致密天体也有可能包含暗物质。NS被认为是检验理论和收集观测数据的最佳天然实验室。我们主要研究费米子和玻色子两类DM粒子，它们的质量范围为[0.01-1.5] GeV，斥力相互作用约为[10-4-10-1] MeV-1。利用双流体模型求解 TOV 方程，我们发现了跨度达数百公里、重量达数十甚至数百个太阳质量的稳定构型。为了使结果形象化，我们把它想象成一个巨大的不可见的紧凑型 DM 天体，而位于中心的 NS 则是核心，是唯一可见的部分。这些构型符合稳定性标准，因此不太可能坍缩成黑洞。我们更进一步，将这一研究成果应用于存在于神秘质量缝隙内部的更小形态。我们还发现了 3-4 个太阳质量的稳定构型，NS-DM 混合能够描述质量间隙。无论如何，如果将目前的理论预测与相应的观测结合起来，就能揭示DM的存在，甚至更多关于其基本性质的信息。

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

Particles

CiteScore

3.20

自引率

0.00%

发文量