Why artificial disruption is not a concern for current cosmological simulations

Feihong He, Jiaxin Han, Zhaozhou Li
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Abstract

Recent studies suggest that cold dark matter subhalos are hard to disrupt and almost all cases of subhalo disruption observed in numerical simulations are due to numerical effects. However, these findings primarily relied on idealized numerical experiments, which do not fully capture the realistic conditions of subhalo evolution within a hierarchical cosmological context. Based on the Aquarius simulations, we identify clear segregation in the population of surviving and disrupted subhalos, which corresponds to two distinct acquisition channels of subhalos. We find that all of the first-order subhalos accreted after redshift 2 survive to the present time without suffering from artificial disruption. On the other hand, most of the disrupted subhalos are sub-subhalos accreted at high redshift. Unlike the first-order subhalos, sub-subhalos experience pre-processing and many of them are accreted through major mergers at high redshift, resulting in very high mass loss rates. We confirm these high mass loss rates are physical through both numerical experiments and semi-analytical modeling, thus supporting a physical origin for their rapid disappearance in the simulation. Even though we cannot verify whether these subhalos have fully disrupted or not, their extreme mass loss rates dictate that they can at most contribute a negligible fraction to the very low mass end of the subhalo mass function. We thus conclude that current state-of-the-art cosmological simulations have reliably resolved the subhalo population.
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为什么目前的宇宙学模拟并不担心人为干扰?
最近的研究表明,冷暗物质亚晕很难被破坏,数值模拟中观测到的几乎所有亚晕破坏案例都是由于数值效应造成的。然而,这些发现主要依赖于理想化的数值实验,并不能完全捕捉到亚晕在层次宇宙学背景下演化的现实条件。基于水瓶座的模拟,我们发现幸存的亚halos和被破坏的亚halos群体存在明显的分离,这对应于亚halos的两个不同的获取通道。我们发现,所有在红移2之后吸积的一阶亚halos都存活到了现在,没有受到人为的破坏。另一方面,大部分被破坏的亚头状星都是在高红移时吸积的亚头状星。与一阶次头状星不同,次头状星经历了预处理,其中许多是通过高红移下的大合并而增生的,因此质量损失率非常高。我们通过数值实验和半解析建模证实了这些高质量损失率是物理现象,从而支持了它们在模拟中迅速出现的物理原因。尽管我们无法验证这些亚halos是否已经完全解体,但它们极高的质量损失率决定了它们最多只能为亚halos质量函数的极低质量端贡献微不足道的一部分。因此我们得出结论,目前最先进的宇宙学模拟已经可靠地解析了亚哈罗星群。
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