On the virialization threshold for halo mass functions

Ronaldo C. Batista
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Abstract

In a recent study by Euclid collaboration, the halo mass function (HMF) has been fitted with accuracy better than $1\%$ for the $\Lambda$CDM model. Several parameters were introduced and fitted against N-body simulations, assuming the usual linearly extrapolated matter density contrast at the collapse time, $\delta_c$, as a basic threshold for halo formation. As a result, a new function that multiplies $\delta_c$ was introduced, producing an effective threshold that varies both with redshift and mass scale. We show that the redshift evolution of this effective threshold is similar to the one of the linear extrapolated matter density contrast at the virialization time, $\delta_{\rm v}$. Assuming the Euclid HMF as a fiducial model, we refit the Sheth-Tormen (ST) HMF using $\delta_{\rm v}$ as a threshold. This new fit improves the agreement between ST-HMF and the Euclid one with respect to Despali et al. (2016) fit, specially at high masses. Interestingly, the parameters $a$ and $p$ in this refit have values closer to the Press-Schechter limit of the ST-HMF, showing that the use of $\delta_{\rm v}$ can provide semi-analytical HMF less dependent on extra parameters. Moreover, we analyze the consistency of the ST-HMF fitted with $\delta_{\rm v}$ in smooth dark energy models with time-varying equation of state, finding an overall good agreement with the evolution of halo abundances expected from the linear evolution of perturbations and the Euclid HMF extrapolated to these scenarios. These findings suggest that the use $\delta_{\rm v}$ as a basic function to describe the threshold for halo formation can be a good guide when considering extrapolations for models beyond $\Lambda$CDM, which are typically harder to study in simulations.
关于光环质量函数的病毒化阈值
在欧几里得(Euclid)合作组织最近的一项研究中,对$\Lambda$CDM模型的光环质量函数(HMF)进行了拟合,拟合精度优于$1\%$。在假定坍缩时间的线性外推物质密度对比$\delta_c$是光环形成的基本阈值的情况下,引入了几个参数并与N-体模拟进行了拟合。结果,引入了一个乘以 $\delta_c$ 的新函数,产生了一个随红移和质量尺度变化的有效阈值。我们证明,这个有效阈值的红移演化与病毒化时间的线性外推物质密度对比($\delta_{\rm v}$)相似。假定欧几里得HMF是一个基准模型,我们用$\delta_{\rm v}$作为阈值来重新拟合谢思-托门(ST)HMF。与Despali等人(2016)的拟合相比,这种新的拟合改进了ST-HMF和Euclid模型之间的一致性,特别是在高质时。有趣的是,这种拟合中的参数$a$和$p$的值更接近ST-HMF的Press-Schechter临界值,这表明使用$\delta_{\rm v}$可以提供对额外参数依赖较少的半解析HMF。此外,我们还分析了在具有时变状态方程的平滑暗能量模型中使用$\delta_{\rm v}$拟合的ST-HMF的一致性,发现它与从扰动的线性演化和欧几里得HMF外推到这些情景中所预期的光环丰度演化总体上吻合得很好。这些发现表明,当考虑对$\Lambda$CDM以外的模型进行外推时,使用$\delta_{\rm v}$作为描述光环形成阈值的基本函数是一个很好的指南,因为这些模型通常在模拟中更难研究。
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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