Pair production due to absorption of 2.2 MeV photons in magnetospheres of X-ray pulsars

IF 10.5 4区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Journal of High Energy Astrophysics Pub Date : 2025-07-08 DOI:10.1016/j.jheap.2025.100420

Emir Tataroglu , Alexander A. Mushtukov

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引用次数: 0

Abstract

Accretion onto strongly magnetized neutron stars in X-ray pulsars (XRPs) produces intense X-ray emission and gamma-ray photons, the latter arising from nuclear reactions and high-energy particle collisions in the stellar atmosphere. These gamma-rays interact with the magnetic field via one- and two-photon pair creation processes, generating electron-positron pairs. We investigate one-photon pair production in sub-critical XRPs, with a focus on how surface magnetic field strength affects gamma-ray absorption in the magnetosphere. Using general relativistic photon trajectory simulations, we map the spatial distribution of pair creation sites and quantify absorption efficiencies. We find that XRPs with surface fields

B ≲ 10^{12} G

are largely transparent to 2.2 MeV gamma-rays, while fields

B ≳ 3 \times 10^{12} G

lead to efficient absorption within a few tens of centimeters from the surface. For lower field strengths, absorption can occur at larger distances and outside the accretion column, offering a potential channel for radio emission. Our results provide new insight into the interplay between nuclear processes, magnetospheric structure, and multiwavelength radiation in XRPs.

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x射线脉冲星磁球吸收2.2 MeV光子产生对

x射线脉冲星（xrp）中强磁化中子星上的吸积产生强烈的x射线发射和伽马射线光子，后者由恒星大气中的核反应和高能粒子碰撞产生。这些伽马射线通过单光子和双光子对产生过程与磁场相互作用，产生电子-正电子对。我们研究了亚临界xrp中的单光子对产生，重点研究了表面磁场强度如何影响磁层中的伽马射线吸收。利用广义相对论的光子轨迹模拟，我们绘制了对产生点的空间分布并量化了吸收效率。我们发现，表面场B > 1012G的XRPs对2.2 MeV的伽马射线基本上是透明的，而表面场B > 3×1012G的XRPs在距离表面几十厘米的范围内可以有效吸收。对于较低的场强，吸收可以发生在较大的距离和吸积柱之外，为射电发射提供了一个潜在的通道。我们的结果为xrp中核过程、磁层结构和多波长辐射之间的相互作用提供了新的见解。

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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.