Chiral interactions, chiral states and “chiral neutrino oscillations”

IF 2.8 3区物理与天体物理 Q2 PHYSICS, PARTICLES & FIELDS

Nuclear Physics B Pub Date : 2025-09-23 DOI:10.1016/j.nuclphysb.2025.117136

A. Yu. Smirnov

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Abstract

In vacuum the “chiral neutrino oscillations”, i.e. the periodic transitions between the left- and right-handed states do not occur. The produced state differs from the chiral component that appear in the Lagrangian of interactions and should be computed for each specific process. The phase difference between components of a produced neutrino is space-time independent. This neutrino state consists of only positive energy solutions of the Dirac equation and therefore the energy splitting

2 E_{ν}

between the components with different helicities that would drive the chiral oscillations does not exist. Consideration in terms of neutrino propagators leads to the same conclusion. The situation is similar for the Majorana neutrinos and in the presence of flavor mixing. However, oscillations of the neutrino states produced in the chiral interactions are possible in matter with the length determined by the matter potential. Description of oscillations in terms of the amplitudes of production and detection is elaborated that does not lead to any misconception. In the expanding Universe the relic neutrinos adiabatically convert to equal number densities of the left and right handed components.

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手性相互作用，手性态和“手性中微子振荡”

在真空中，“手性中微子振荡”，即左手态和右手态之间的周期性转变不会发生。产生态不同于拉格朗日相互作用中出现的手性分量，应该对每个特定过程进行计算。产生的中微子的组成部分之间的相位差与时空无关。这种中微子状态仅由狄拉克方程的正能量解组成，因此在具有不同螺旋度的组分之间不存在驱动手性振荡的能量分裂2ev。对中微子传播体的考虑也得出了同样的结论。马约拉纳中微子的情况与风味混合存在的情况类似。然而，手性相互作用中产生的中微子态振荡在物质中是可能的，其长度由物质势决定。根据产生和检测的振幅来描述振荡，这不会导致任何误解。在膨胀的宇宙中，残留的中微子绝热地转化为相同数量密度的左旋和右旋成分。

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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来源期刊

Nuclear Physics B 物理-物理：粒子与场物理

CiteScore

5.50

自引率

7.10%

发文量

302

审稿时长

1 months

期刊介绍： Nuclear Physics B focuses on the domain of high energy physics, quantum field theory, statistical systems, and mathematical physics, and includes four main sections: high energy physics - phenomenology, high energy physics - theory, high energy physics - experiment, and quantum field theory, statistical systems, and mathematical physics. The emphasis is on original research papers (Frontiers Articles or Full Length Articles), but Review Articles are also welcome.