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Main Authors: Zhou, Jie, Zhao, Ying Shan, Sun, Yifeng
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.20083
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author Zhou, Jie
Zhao, Ying Shan
Sun, Yifeng
author_facet Zhou, Jie
Zhao, Ying Shan
Sun, Yifeng
contents A strong classical color field, known as the glasma, is generated in the earliest stage of relativistic heavy-ion collisions and can significantly influence the momentum and spin dynamics of hard probes such as quarks and jets. Most existing studies based on the classical equations of motion in a background Yang-Mills field, such as Wong equations, may not capture the full range of effects, for example, they neglect the Stern-Gerlach force experienced by spinning particles in non-uniform glasma fields. Although several extensions of Wong equations have been proposed to include spin degrees of freedom, they generally fail to satisfy all the required conditions simultaneously, such as Lorentz covariance, allowance for an arbitrary chromomagnetic moment, and respect for the necessary physical constraints. In this work, we extend the framework of a relativistic classical spinning particle in an electromagnetic field to describe spin one-half quarks propagating in a background non-Abelian Yang-Mills field. By systematically applying the Dirac-Bergmann algorithm, we derive self-consistent equations of motion for the particle's coordinates, momenta, spin, and color charge that satisfy all these requirements. This formalism provides a more complete and physically relevant description for studying momentum diffusion and spin polarization phenomena of hard probes in the glasma.
format Preprint
id arxiv_https___arxiv_org_abs_2511_20083
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The covariant equations of motion of massive spinning particles in a background Yang-Mills field
Zhou, Jie
Zhao, Ying Shan
Sun, Yifeng
Nuclear Theory
High Energy Physics - Theory
A strong classical color field, known as the glasma, is generated in the earliest stage of relativistic heavy-ion collisions and can significantly influence the momentum and spin dynamics of hard probes such as quarks and jets. Most existing studies based on the classical equations of motion in a background Yang-Mills field, such as Wong equations, may not capture the full range of effects, for example, they neglect the Stern-Gerlach force experienced by spinning particles in non-uniform glasma fields. Although several extensions of Wong equations have been proposed to include spin degrees of freedom, they generally fail to satisfy all the required conditions simultaneously, such as Lorentz covariance, allowance for an arbitrary chromomagnetic moment, and respect for the necessary physical constraints. In this work, we extend the framework of a relativistic classical spinning particle in an electromagnetic field to describe spin one-half quarks propagating in a background non-Abelian Yang-Mills field. By systematically applying the Dirac-Bergmann algorithm, we derive self-consistent equations of motion for the particle's coordinates, momenta, spin, and color charge that satisfy all these requirements. This formalism provides a more complete and physically relevant description for studying momentum diffusion and spin polarization phenomena of hard probes in the glasma.
title The covariant equations of motion of massive spinning particles in a background Yang-Mills field
topic Nuclear Theory
High Energy Physics - Theory
url https://arxiv.org/abs/2511.20083