Anisotropic charge transport in strongly magnetized relativistic matter

IF 4.2 2区物理与天体物理 Q2 PHYSICS, PARTICLES & FIELDS

The European Physical Journal C Pub Date : 2024-11-19 DOI:10.1140/epjc/s10052-024-13570-3

Ritesh Ghosh, Igor A. Shovkovy

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Abstract

We investigate electrical charge transport in hot magnetized plasma using first-principles quantum field theoretical methods. By employing Kubo’s linear response theory, we express the electrical conductivity tensor in terms of the fermion damping rate in the Landau-level representation. Utilizing leading-order results for the damping rates from a recent study within a gauge theory, we derive the transverse and longitudinal conductivities for a strongly magnetized plasma. The analytical expressions reveal drastically different mechanisms that explain the high anisotropy of charge transport in a magnetized plasma. Specifically, the transverse conductivity is suppressed, while the longitudinal conductivity is enhanced by a strong magnetic field. As in the case of zero magnetic field, longitudinal conduction is determined by the probability of charge carriers to remain in their quantum states without damping. In contrast, transverse conduction critically relies on quantum transitions between Landau levels, effectively lifting charge trapping in localized Landau orbits. We examine the temperature and magnetic field dependence of the transverse and longitudinal electrical conductivities over a wide range of parameters and investigate the effects of a nonzero chemical potential. Additionally, we extend our analysis to strongly coupled quark-gluon plasma and study the impact of the coupling constant on the anisotropy of electrical charge transport.

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强磁化相对论物质中的各向异性电荷传输

我们利用第一原理量子场论方法研究了热磁化等离子体中的电荷传输。通过采用久保的线性响应理论，我们用朗道级表示中的费米子阻尼率来表达电导张量。利用最近在量规理论中研究得出的阻尼率前沿结果，我们推导出了强磁化等离子体的横向和纵向电导率。分析表达式揭示了解释磁化等离子体中电荷传输高度各向异性的截然不同的机制。具体来说，强磁场会抑制横向电导率，而增强纵向电导率。与零磁场的情况一样，纵向传导取决于电荷载流子在没有阻尼的情况下保持其量子态的概率。与此相反，横向传导主要依赖于朗道水平之间的量子跃迁，从而有效解除局部朗道轨道中的电荷捕获。我们研究了横向和纵向电导率在较大参数范围内对温度和磁场的依赖性，并探讨了非零化学势的影响。此外，我们还将分析扩展到了强耦合夸克-胶子等离子体，并研究了耦合常数对电荷传输各向异性的影响。

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来源期刊

The European Physical Journal C 物理-物理：粒子与场物理

CiteScore

8.10

自引率

15.90%

发文量

1008

审稿时长

2-4 weeks

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