Instability of Electroweak Homogeneous Vacua in Strong Magnetic Fields

IF 1.4 3区物理与天体物理 Q2 PHYSICS, MATHEMATICAL

Annales Henri Poincaré Pub Date : 2024-03-19 DOI:10.1007/s00023-024-01430-5

Adam Gardner, Israel Michael Sigal

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Abstract

We consider the classical vacua of the Weinberg–Salam (WS) model of electroweak forces. These are no-particle, static solutions to the WS equations minimizing the WS energy locally. We study the WS vacuum solutions exhibiting a non-vanishing average magnetic field of strength b and prove that (i) there is a magnetic field threshold \(b_*\) such that for \(b<b_*\), the vacua are translationally invariant (and the magnetic field is constant), while, for \(b>b_*\), they are not, (ii) for \(b>b_*\), there are non-translationally invariant solutions with lower energy per unit volume and with the discrete translational symmetry of a 2D lattice in the plane transversal to b, and (iii) the lattice minimizing the energy per unit volume approaches the hexagonal one as the magnetic field strength approaches the threshold \(b_*\). In the absence of particles, the Weinberg–Salam model reduces to the Yang–Mills–Higgs (YMH) equations for the gauge group U(2). Thus, our results can be rephrased as the corresponding statements about the U(2)-YMH equations.

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强磁场中的电弱同质虚空的不稳定性

我们考虑了电弱力的温伯格-萨拉姆（WS）模型的经典虚空。它们是 WS 方程的无粒子静态解，局部最小化了 WS 能量。b_*\）时，存在单位体积能量较低的非平移不变解，并且在横向于 b 的平面上具有二维晶格的离散平移对称性；(iii) 当磁场强度接近临界值 \（b_*\）时，单位体积能量最小的晶格接近六边形晶格。在没有粒子的情况下，温伯格-萨拉姆模型可以还原为杨-米尔斯-希格斯（Yang-Mills-Higgs，YMH）方程。因此，我们的结果可以表述为关于U(2)-YMH方程的相应陈述。

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

Annales Henri Poincaré 物理-物理：粒子与场物理

CiteScore

3.00

自引率

6.70%

发文量

108

审稿时长

6-12 weeks

期刊介绍： The two journals Annales de l''Institut Henri Poincaré, physique théorique and Helvetica Physical Acta merged into a single new journal under the name Annales Henri Poincaré - A Journal of Theoretical and Mathematical Physics edited jointly by the Institut Henri Poincaré and by the Swiss Physical Society. The goal of the journal is to serve the international scientific community in theoretical and mathematical physics by collecting and publishing original research papers meeting the highest professional standards in the field. The emphasis will be on analytical theoretical and mathematical physics in a broad sense.