Cosmic-ray deuteron excess from a primary component

arXiv - PHYS - High Energy Physics - Phenomenology Pub Date : 2024-09-11 DOI:arxiv-2409.07139

Xing-Jian Lv, Xiao-Jun Bi, Kun Fang, Peng-Fei Yin, Meng-Jie Zhao

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Abstract

The recent AMS-02 measurements of cosmic-ray (CR) deuteron fluxes suggest the presence of primary deuterons in quantities far exceeding predictions from Big Bang nucleosynthesis. This poses a significant challenge to modern astrophysics, as no known processes can account for such large amounts of deuterons without violating existing constraints~\cite{Epstein:1976hq}. In contrast, it is recently proposed that the AMS-02 measurements can be explained by a purely secondary origin when contributions from heavier nuclei are considered. In this study, we recalculate the secondary deuteron flux using production cross sections updated with the latest collider data. We find that some of the deuteron production cross sections are overestimated in the widely-used calculation tools for CR propagation, and a primary deuteron component is still necessary. We then propose a novel process for generating primary deuterons at CR sources through a fusion mechanism, which is naturally unique to deuterons. This model could explain the observed deuteron excess while maintaining consistency with other CR measurements.

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主成分的宇宙射线氘核过量

最近对宇宙射线（CR）氘核通量的AMS-02测量表明，原生氘核的存在远远超出了大爆炸核合成的预测。这对现代天体物理学提出了重大挑战，因为没有任何已知过程能够在不违反现有约束条件的情况下解释如此大量的氘核~cite{Epstein:1976hq}。与此相反，最近有人提出，如果考虑到来自更重原子核的贡献，AMS-02 的测量结果可以用纯粹的二次起源来解释。在这项研究中，我们利用最新对撞机数据更新的产生截面重新计算了二次氘核通量。我们发现，在广泛使用的CR传播计算工具中，一些氘核产生截面被高估了，一次氘核成分仍然是必要的。然后，我们提出了一种在CR源通过核聚变机制产生初级氘核的新过程，这自然是氘核所独有的。这一模型可以解释观测到的氘核过量，同时与其他 CR 测量结果保持一致。

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 - PHYS - High Energy Physics - Phenomenology

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