模拟日冕磁场存在时宇宙射线与太阳大气相互作用产生的伽马射线* * 中国得到国家自然科学基金委员会的资助(12261160362,12022502)。国家自然科学基金委员会(12322517,N_CUHK456/22)和研究资助局(24302721,14305822,14308023)的资助。

IF 3.6 2区 物理与天体物理 Q1 PHYSICS, NUCLEAR
Zhe Li, Kenny C. Y. Ng, Songzhan Chen, Yuncheng Nan, Huihai He
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引用次数: 0

摘要

宇宙射线可以与太阳大气相互作用,产生一系列次级信使,使太阳成为天空中明亮的伽马射线源。利用费米-LAT 进行的详细观测表明,这些相互作用必须受到太阳磁场的强烈影响,才能产生各种观测特征,例如高通量和硬光谱。然而,这些特征背后的详细机制仍然是一个谜。在这项研究中,我们利用势场源表面(PFSS)模型,在存在日冕磁场的太阳大气中进行了粒子相互作用模拟,从而解决了这个问题。我们发现,日冕磁场显著增强了低能(〜 GeV)伽马射线的产生,但增强程度随着能量的增加而迅速降低。这种增强与相对于输入宇宙射线方向的大偏角伽马射线的产生直接相关。我们的结论是,日冕磁场对于正确模拟 10 GeV 以下的太阳盘伽马射线是必不可少的,但在 10 GeV 以上,日冕磁场的作用就会减弱。需要其他磁场结构来解释高能磁盘辐射。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simulating gamma-ray production from cosmic rays interacting with the solar atmosphere in the presence of coronal magnetic fields* * Supported in China by the NSFC (12261160362, 12022502). KCYN is supported by grants provided by the NSFC (12322517, N_CUHK456/22) and RGC (24302721, 14305822, 14308023)
Cosmic rays can interact with the solar atmosphere and produce a slew of secondary messengers, making the Sun a bright gamma-ray source in the sky. Detailed observations with Fermi-LAT have shown that these interactions must be strongly affected by solar magnetic fields in order to produce a wide range of observational features, such as a high flux and hard spectrum. However, the detailed mechanisms behind these features are still a mystery. In this study, we tackle this problem by performing particle-interaction simulations in the solar atmosphere in the presence of coronal magnetic fields using the potential field source surface (PFSS) model. We find that low-energy (~ GeV) gamma-ray production is significantly enhanced by the coronal magnetic fields, but the enhancement decreases rapidly with energy. The enhancement directly correlates with the production of gamma rays with large deviation angles relative to the input cosmic-ray direction. We conclude that coronal magnetic fields are essential for correctly modeling solar disk gamma rays below 10 GeV, but above that, the effect of coronal magnetic fields diminishes. Other magnetic field structures are needed to explain the high-energy disk emission.
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来源期刊
中国物理C
中国物理C 物理-物理:核物理
CiteScore
6.50
自引率
8.30%
发文量
8976
审稿时长
1.3 months
期刊介绍: Chinese Physics C covers the latest developments and achievements in the theory, experiment and applications of: Particle physics; Nuclear physics; Particle and nuclear astrophysics; Cosmology; Accelerator physics. The journal publishes original research papers, letters and reviews. The Letters section covers short reports on the latest important scientific results, published as quickly as possible. Such breakthrough research articles are a high priority for publication. The Editorial Board is composed of about fifty distinguished physicists, who are responsible for the review of submitted papers and who ensure the scientific quality of the journal. The journal has been awarded the Chinese Academy of Sciences ‘Excellent Journal’ award multiple times, and is recognized as one of China''s top one hundred key scientific periodicals by the General Administration of News and Publications.
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