# Axion electrodynamics: Green's functions, zero-point energy and optical   activity

**Authors:** Amedeo M. Favitta, Iver Brevik, Masud Chaichian

arXiv: 2302.13129 · 2023-08-09

## TL;DR

This paper explores the effects of axion fields on electromagnetic phenomena, including Casimir energy modifications and radiation pressure on domain walls, extending theories to finite temperatures and connecting to condensed matter systems.

## Contribution

It extends Axion Electrodynamics theory to include finite temperature effects and applies Green's function methods to analyze Casimir forces and radiation pressure in axionic contexts.

## Key findings

- Modified Casimir force due to axion fields
- Calculated radiation pressure on axion domain walls
- Extended theory to finite temperature scenarios

## Abstract

Starting from the theory of Axion Electrodynamics, we work out the axionic modifications to the electromagnetic Casimir energy using the Green's function, both when the axion field is initially assumed purely time-dependent and when the axion field configuration is a static domain wall. For the first case it means that the oscillating axion background is taken to resemble an axion fluid at rest in a conventional Casimir setup with two infinite parallel conducting plates, while in the second case we evaluate the radiation pressure acting on an axion domain wall. We extend previous theories in order to include finite temperatures. Various applications are discussed. 1. We review the theory of Axion Electrodynamics and particularly the energy-momentum conservation in a linear dielectric and magnetic material. We treat this last aspect by extending former results by Brevik and Chaichian (2022) and Patkos (2022). 2. Adopting the model of the oscillating axion background we discuss the axion-induced modifications to the Casimir force between two parallel plates by using a Green's function approach. 3. We calculate the radiation pressure acting on an axion domain wall at finite temperature T. Our results for an oscillating axion field and a domain wall are also useful for condensed matter physics, where "axionic topological insulators" interact with the electromagnetic field with a Chern-Simons interaction, like the one in Axion Electrodynamics, and there are experimental systems analogous to time-dependent axion fields and domain walls as the ones showed by Jiang, Q. D., \& Wilczek, F. (2019) and Fukushima et al. (2019). 4. We compare our results, where we assume time-dependent or space-dependent axion configurations, with the discussion of the optical activity of Axion Electrodynamics by Sikivie (2021) and Carrol et al. (1990).

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/2302.13129/full.md

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/2302.13129/full.md

## References

49 references — full list in the complete paper: https://tomesphere.com/paper/2302.13129/full.md

---
Source: https://tomesphere.com/paper/2302.13129