Equilibrium chiral magnetic effect: Spatial inhomogeneity, finite temperature, interactions

Chitradip Banerjee; Meir Lewkowicz; Mikhail A. Zubkov

doi:10.1016/j.physletb.2021.136457

Equilibrium chiral magnetic effect: Spatial inhomogeneity, finite temperature, interactions

Chitradip Banerjee, Meir Lewkowicz, Mikhail A. Zubkov

Department of Physics

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

We discuss equilibrium relativistic fermionic systems in lattice regularization, and extend the consideration of chiral magnetic effect to systems with spatial inhomogeneity and finite temperature. Besides, we take into account interactions due to exchange by gauge bosons. We find that the equilibrium chiral magnetic conductivity remains equal to zero.

Original language	English
Article number	136457
Journal	Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics
Volume	819
DOIs	https://doi.org/10.1016/j.physletb.2021.136457
State	Published - 10 Aug 2021

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10.1016/j.physletb.2021.136457

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title = "Equilibrium chiral magnetic effect: Spatial inhomogeneity, finite temperature, interactions",

abstract = "We discuss equilibrium relativistic fermionic systems in lattice regularization, and extend the consideration of chiral magnetic effect to systems with spatial inhomogeneity and finite temperature. Besides, we take into account interactions due to exchange by gauge bosons. We find that the equilibrium chiral magnetic conductivity remains equal to zero.",

author = "Chitradip Banerjee and Meir Lewkowicz and Zubkov, {Mikhail A.}",

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T2 - Spatial inhomogeneity, finite temperature, interactions

AU - Banerjee, Chitradip

AU - Lewkowicz, Meir

AU - Zubkov, Mikhail A.

PY - 2021/8/10

Y1 - 2021/8/10

N2 - We discuss equilibrium relativistic fermionic systems in lattice regularization, and extend the consideration of chiral magnetic effect to systems with spatial inhomogeneity and finite temperature. Besides, we take into account interactions due to exchange by gauge bosons. We find that the equilibrium chiral magnetic conductivity remains equal to zero.

AB - We discuss equilibrium relativistic fermionic systems in lattice regularization, and extend the consideration of chiral magnetic effect to systems with spatial inhomogeneity and finite temperature. Besides, we take into account interactions due to exchange by gauge bosons. We find that the equilibrium chiral magnetic conductivity remains equal to zero.

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AN - SCOPUS:85108403879

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M1 - 136457

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Equilibrium chiral magnetic effect: Spatial inhomogeneity, finite temperature, interactions

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