Laboratory constraint on the electric charge of the neutron and the neutrino

IF 1.5 4区物理与天体物理 Q3 OPTICS The European Physical Journal D Pub Date : 2025-04-02 DOI:10.1140/epjd/s10053-025-00964-5

Savely G. Karshenboim

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Abstract

We revisit constraints on the value of the electric charge of the neutron and the neutrinos as well as on the electric-charge proton–electron difference \(e_p+e_e\). We consider phenomenological constraints based on laboratory study of the electrical neutrality of would-be neutral subatomic, atomic, and molecular species under assumption of the conservation of the electric charge in the \(\beta \) decay that relates the values of \(e_p+e_e, e_n, e_\nu \). Some of constraints published previously utilized an additional assumption \(e_\nu =0\), which we do not. We dismiss a cosmological constraint at the level of \(10^{-35}\,e\) utilized by Particle Data Group (PDG) in their Review of particle properties Workman et al. (Particle Data Group) (Prog Theor Exp Phys 2022:083C01, 2022) as a controversial one which makes the laboratory constraints on \(e_\nu \) dominant. The phenomenological constraints from the available data of laboratory experiments are obtained as \(e_p+e_e=(0.2\pm 2.6)\times 10^{-21}\,e\), \(e_n=(-0.4\pm 1.1)\times 10^{-21}\,e\), and \(e_\nu =(0.6\pm 3.2)\times 10^{-21}\,e\). The ones on \(e_p+e_e\) and \(e_n\) are at the same level as the related constraints of PDG but somewhat different because of releasing the value of \(e_\nu \). Our \(e_\nu \) constraint is several orders of magnitude weaker than the controversial cosmological result dominated in the PDG constraint, but several orders of magnitude stronger than the other individual \(e_\nu \) constraints considered by PDG. We also consider consistency of the phenomenological constraints and the Standard Model (SM). The SM ignores the mass term of the neutrinos and cannot describe the neutrino oscillations which makes it not a complete theory but a part of it. We demonstrate that the condition of the cancellation of the triangle anomalies within the complete theory does not disagree with the phenomenological constraints since different extensions of the SM may produce different additional contributions to the anomalies. A choice of the extension fixes the way how those contributions are organized. In particular, we consider a minimal extension of the SM, where leptons (\(\nu ,e\)) are treated the same ways as quarks, which sets \(e_p+e_e=0\) and allows for numerical strengthening the constraint on \(e_n\) and \(e_\nu \), which is \(e_n=-e_\nu =(-0.4\pm 1.0)\times 10^{-21}\,e\).

Phenomenological constraint on the value of the electric charge of the neutrino

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中子和中微子电荷的实验室约束

我们重新审视中子和中微子的电荷值以及电荷质子-电子差\(e_p+e_e\)的约束。我们考虑现象学约束，基于实验室研究的电中性的准中性亚原子，原子和分子物种的假设下，在与\(e_p+e_e, e_n, e_\nu \)值相关的\(\beta \)衰变中的电荷守恒。以前发布的一些约束使用了一个额外的假设\(e_\nu =0\)，而我们没有。我们不考虑粒子数据组（PDG）在其粒子性质评论中使用的\(10^{-35}\,e\)级别的宇宙学约束(Workman等人（粒子数据组）（Prog theory Exp Phys 2022: 083c01, 2022），因为这是一个有争议的约束，使得\(e_\nu \)的实验室约束占主导地位。从现有实验室实验数据得到的现象学约束为\(e_p+e_e=(0.2\pm 2.6)\times 10^{-21}\,e\), \(e_n=(-0.4\pm 1.1)\times 10^{-21}\,e\)和\(e_\nu =(0.6\pm 3.2)\times 10^{-21}\,e\)。\(e_p+e_e\)和\(e_n\)上的约束与PDG的相关约束处于同一水平，但由于释放了\(e_\nu \)的值而有所不同。我们的\(e_\nu \)约束比PDG约束中主导的有争议的宇宙学结果弱几个数量级，但比PDG考虑的其他个别\(e_\nu \)约束强几个数量级。我们还考虑了现象学约束与标准模型（SM）的一致性。SM忽略了中微子的质量项，不能描述中微子的振荡，这使得它不是一个完整的理论，而是它的一部分。我们证明了在完全理论中三角形异常消除的条件与现象学约束并不矛盾，因为SM的不同扩展可能对异常产生不同的附加贡献。扩展的选择修复了这些贡献的组织方式。特别地，我们考虑了SM的最小扩展，其中轻子（\(\nu ,e\)）被视为与夸克相同的方式，这设置了\(e_p+e_e=0\)，并允许在数值上加强对\(e_n\)和\(e_\nu \)的约束，这是\(e_n=-e_\nu =(-0.4\pm 1.0)\times 10^{-21}\,e\) .中微子电荷值的现象学约束

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来源期刊

The European Physical Journal D 物理-物理：原子、分子和化学物理

CiteScore

3.10

自引率

11.10%

发文量

213

审稿时长

3 months

期刊介绍： The European Physical Journal D (EPJ D) presents new and original research results in: Atomic Physics; Molecular Physics and Chemical Physics; Atomic and Molecular Collisions; Clusters and Nanostructures; Plasma Physics; Laser Cooling and Quantum Gas; Nonlinear Dynamics; Optical Physics; Quantum Optics and Quantum Information; Ultraintense and Ultrashort Laser Fields. The range of topics covered in these areas is extensive, from Molecular Interaction and Reactivity to Spectroscopy and Thermodynamics of Clusters, from Atomic Optics to Bose-Einstein Condensation to Femtochemistry.