Effect of the crust on neutron star empirical relations

arXiv: Nuclear Theory Pub Date : 2020-10-12 DOI:10.1103/physrevd.102.103003

Márcio Ferreira, C. Providencia

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引用次数: 7

Abstract

We analyze how the crust equation of state affects several neutron star properties and how it impacts on possible constraints inferred from astrophysical observations. Using three distinct crusts, we generate three sets of model-independent equations of state describing stellar matter from a Taylor expansion around saturation density. The equations of state are thermodynamically consistent, causal, and compatible with astrophysical observations. The relations between the tidal deformability $\Lambda$ and compactness $C$, Love number $k_2$ and radius of neutron star with mass $M$ are studied, and the effect of the crust equation of state on these relations analyzed. In most of the relations, the impact of the crust equation of state is not larger that 2\%. If, however, a fixed neutron star mass is considered, the relation between the tidal deformability and the radius depends on the crust. We have found that the relation $\Lambda_{M_i} = \alpha R_{M_i}^{\beta}$ becomes almost exact and crust independent for massive neutron stars. It is shown that it is possible to determine the tidal deformability of an 1.4$M_\odot$ star from the GW179817 effective tidal deformability $\tilde\Lambda$ with an accuracy of at least $\approx 10\%$. A high correlation between $\tilde\Lambda$ and the radius of the most massive star of the neutron star binary was confirmed, however, it was demonstrated that the crust has an effect of $\approx 14\%$ on this relation. We have found that the relation $\Lambda_1/\Lambda_2=q^a$ depends on $M_{\text{chirp}}$ as $a\sim \sqrt{M_{\text{chirp}}}$.

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地壳对中子星经验关系的影响

我们分析了地壳状态方程如何影响几种中子星性质，以及它如何影响从天体物理观测推断的可能约束。使用三个不同的地壳，我们生成了三组独立于模型的状态方程，描述了围绕饱和密度的泰勒膨胀的恒星物质。状态方程在热力学上是一致的、因果的，并且与天体物理观测相一致。研究了潮汐变形能力$\Lambda$与致密度$C$、勒夫数$k_2$与中子星半径$M$的关系，并分析了地壳状态方程对这些关系的影响。在大多数关系中，地壳状态方程的影响不大于2％。但是，如果考虑一个固定的中子星质量，则潮汐变形能力与半径之间的关系取决于地壳。我们发现，对于大质量中子星，$\Lambda_{M_i} = \alpha R_{M_i}^{\beta}$的关系几乎是精确的，并且与地壳无关。结果表明，利用GW179817有效潮汐可变形性$\tilde\Lambda$可以确定1.4 $M_\odot$恒星的潮汐可变形性，其精度至少为$\approx 10\%$。证实了$\tilde\Lambda$与中子星双星中质量最大的恒星的半径之间的高度相关性，然而，证明了地壳对这种关系有$\approx 14\%$的影响。我们发现关系$\Lambda_1/\Lambda_2=q^a$依赖于$M_{\text{chirp}}$和$a\sim \sqrt{M_{\text{chirp}}}$。

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: Nuclear Theory

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