Cooling of neutron stars in soft X-ray transients with realistic crust composition

IF 10.2 4区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS Journal of High Energy Astrophysics Pub Date : 2024-11-26 DOI:10.1016/j.jheap.2024.11.017

A.Y. Potekhin , A.I. Chugunov , N.N. Shchechilin , M.E. Gusakov

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Abstract

Thermal radiation of neutron stars in soft X-ray transients (SXTs) in a quiescent state is believed to be powered by the heat deposited in the stellar crust due to nuclear reactions during accretion. Confronting observations of this radiation with simulations helps to verify theoretical models of the dense matter in neutron stars. We simulate the thermal evolution of the SXTs with theoretical models of the equation of state and composition of the accreted crust. The new family of such models were recently developed within a thermodynamically consistent approach by modeling the nuclear evolution of an accreted matter as it sinks toward the stellar center, starting from representative thermonuclear ash compositions. The crust cooling curves computed with the traditional and modern theory are compared with observations of SXTs MXB 1659−29 and IGR J17480−2446. We show that the new and traditional models of the accreted neutron star crusts are similar in their capability to explain the thermal evolution of neutron stars in SXTs. Both kinds of models require inclusion of additional ingredients not supplied by the current theory, such as the shallow heating and variation of thermal conductivity, to fit observations.

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软 X 射线瞬变中中子星的冷却与现实的外壳组成

处于静态的软X射线瞬态（SXT）中子星的热辐射被认为是由吸积过程中的核反应在恒星外壳中沉积的热量驱动的。通过模拟观测这种辐射有助于验证中子星致密物质的理论模型。我们用吸积外壳的状态方程和组成的理论模型模拟了中子星的热演化。这类模型的新系列是最近在热力学一致的方法中开发出来的，通过模拟吸积物质在向恒星中心下沉过程中的核演化，从具有代表性的热核灰成分开始。我们将用传统理论和现代理论计算出的结壳冷却曲线与对小行星 MXB 1659-29 和 IGR J17480-2446 的观测结果进行了比较。结果表明，新的和传统的中子星吸积外壳模型在解释SXTs中子星热演化的能力上是相似的。这两种模型都需要加入当前理论没有提供的额外成分，如浅层加热和热导率的变化，才能符合观测结果。

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来源期刊

Journal of High Energy Astrophysics Earth and Planetary Sciences-Space and Planetary Science

CiteScore

9.70

自引率

5.30%

发文量

审稿时长

65 days

期刊介绍： The journal welcomes manuscripts on theoretical models, simulations, and observations of highly energetic astrophysical objects both in our Galaxy and beyond. Among those, black holes at all scales, neutron stars, pulsars and their nebula, binaries, novae and supernovae, their remnants, active galaxies, and clusters are just a few examples. The journal will consider research across the whole electromagnetic spectrum, as well as research using various messengers, such as gravitational waves or neutrinos. Effects of high-energy phenomena on cosmology and star-formation, results from dedicated surveys expanding the knowledge of extreme environments, and astrophysical implications of dark matter are also welcomed topics.