宇宙学中微子及其对宇宙演化的影响

IF 0.8 4区 地球科学 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC Radiophysics and Quantum Electronics Pub Date : 2024-07-05 DOI:10.1007/s11141-024-10324-9
A. V. Ivanchik, O. A. Kurichin, V. Yu. Yurchenko
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引用次数: 0

摘要

作为标准模型中最神秘的粒子之一,中微子为天体物理研究带来了新的机遇。中微子的穿透力很强,可以让我们深入了解恒星内部,并有可能研究超高能量宇宙射线的起源机制。当恒星爆炸时,中微子耀斑会比电磁辐射早几个小时向我们通报这一事件。中微子在宇宙学中也起着至关重要的作用,它是宇宙中已知第二丰富的粒子。在辐射主导的时代,中微子与光子一起决定了宇宙膨胀的动力学。后来,中微子变成了非相对论物质,增加了非相对论物质的贡献Ωm,而之前的非相对论物质包括冷暗物质和重子物质。由于中微子会影响宇宙的演化过程,因此在确定宇宙学参数时应考虑到这一事实。最近,除了来自大爆炸的遗迹中微子之外,理论上还预测了原始核合成的反中微子。目前一些独立实验的结果表明,有可能存在一种轻型不育中微子(mν ~ 1-3 eV)。这种中微子的存在与标准宇宙学模型的预测并不一致,但这些矛盾可以通过扩展标准宇宙学模型来消除,例如,通过宇宙中存在的非零轻子不对称性ξν ~ 10-2。如今,人们对宇宙学中微子的存在已经没有什么怀疑了,但遗憾的是,由于它们在低能下的相互作用截面极小,还无法直接探测到它们。不过,如果将来能做到这一点,我们就能直接获得宇宙大爆炸后最初几秒、几分钟和几小时的演化信息。本文回顾了宇宙学中微子对从早期宇宙(原始核合成和原始重组)到现在不同阶段宇宙演化的影响的主要方面。
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Cosmological Neutrinos and Their Influence on the Evolution of the Universe

Being one of the most mysterious particles of the Standard Model, neutrinos have opened up new opportunities for astrophysical research. The high penetrating power of neutrinos provides insight into stellar interior and makes it possible to study the mechanisms of the origin of ultra-high energy cosmic rays. When a star explodes, a neutrino flare informs us about this event several hours earlier than electromagnetic radiation. Neutrino also plays a crucial role in cosmology, being the second most abundant known particle in the Universe. In the radiation-dominated epoch, neutrinos together with photons, determine the dynamics of the expansion of the Universe. Later, becoming nonrelativistic, the neutrinos increase the contribution Ωm of nonrelativistic matter, which previously consisted of cold dark matter and baryonic matter. Since neutrinos affect the course of the evolution of the Universe, this fact should be taken into account when determining cosmological parameters. Recently, in addition to relic neutrinos from the Big Bang, antineutrinos of primordial nucleosynthesis have been theoretically predicted. Their detection could be additional evidence for baryon asymmetry of the Universe.

Current results from a number of independent experiments indicate the possibility of the existence of a light sterile neutrino (mν ~ 1–3 eV). The presence of such a neutrino is in poor agreement with the predictions of the Standard Cosmological Model, but these contradictions can be removed by its extension, for example, by the existence of a nonzero lepton asymmetry ξν ~ 10−2 of the Universe. Nowadays, there are little doubts about the existence of cosmological neutrinos, but unfortunately it is not yet possible to detect them directly due to the extremely small cross section of their interaction at low energies. However, if this can be done in the future, we will obtain direct information about the first seconds, minutes, and hours of the evolution of the Universe after the Big Bang. A review of key aspects related to the influence of cosmological neutrinos on the evolution of the Universe at different stages from the early Universe (primordial nucleosynthesis and primordial recombination) to present days is given.

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来源期刊
Radiophysics and Quantum Electronics
Radiophysics and Quantum Electronics ENGINEERING, ELECTRICAL & ELECTRONIC-PHYSICS, APPLIED
CiteScore
1.10
自引率
12.50%
发文量
60
审稿时长
6-12 weeks
期刊介绍: Radiophysics and Quantum Electronics contains the most recent and best Russian research on topics such as: Radio astronomy; Plasma astrophysics; Ionospheric, atmospheric and oceanic physics; Radiowave propagation; Quantum radiophysics; Pphysics of oscillations and waves; Physics of plasmas; Statistical radiophysics; Electrodynamics; Vacuum and plasma electronics; Acoustics; Solid-state electronics. Radiophysics and Quantum Electronics is a translation of the Russian journal Izvestiya VUZ. Radiofizika, published by the Radiophysical Research Institute and N.I. Lobachevsky State University at Nizhnii Novgorod, Russia. The Russian volume-year is published in English beginning in April. All articles are peer-reviewed.
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