# Electromagnetism at finite temperature: a density operator approach

**Authors:** Daigo Oue

arXiv: 1906.05219 · 2019-12-17

## TL;DR

This paper introduces an optical density operator to analyze classical electromagnetism at finite temperature, revealing how thermal states affect electromagnetic wave properties and correlations.

## Contribution

It reformulates Maxwell's equations using a density operator approach and analyzes the thermal states of electromagnetic fields in media at different temperatures.

## Key findings

- Transverse modes exist at equal ratios in thermal states.
- Electromagnetic wave correlations appear at low temperatures.
- Correlations vanish at high temperatures, indicating wave dissipation.

## Abstract

In order to analyse classical electromagnetism in a medium at finite temperature we introduce `an optical density operator', and reformulate Maxwell's equations with the operator, starting from the Dirac-equation-like formulation of electromagnetism. We find the thermal state of electromagnetic field in the medium from the `optical Dirac Hamiltonian', which is the effective Hamiltonian in the Dirac-like formulation. In the thermal state, the two transverse modes (left-handed and right-handed circular polarisation) of electromagnetic fields exist at the same ratio. We also analyse the asymptotics of the thermal state. At the low temperature limit, there is correlation between the electric field and the magnetic field. This means that there exists an electromagnetic wave at the thermal equilibrium, and this recovers Maxwell's classical electromagnetism. In contrast, the correlation vanishes at the high temperature limit. This means that electromagnetic waves are unsustainable and only independent electric fields and magnetic fields exist at the high temperature limit.

## Full text

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## Figures

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## References

35 references — full list in the complete paper: https://tomesphere.com/paper/1906.05219/full.md

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Source: https://tomesphere.com/paper/1906.05219