Cavity resonances dominating the photon statistics in the non-equilibrium steady state

TL;DR

This paper theoretically analyzes the non-equilibrium steady state of photons in a cavity with temperature gradients, revealing the significant influence of cavity resonances on photon spectra and deviations from black-body behavior.

Contribution

It derives an analytic expression for the photon spectrum in non-equilibrium cavities and highlights the dominant role of cavity resonances in shaping the steady state.

Findings

Differences between NEST and black-body spectrum can exceed 10%.

Cavity resonances significantly influence the photon distribution.

Non-equilibrium spectra are important for high-precision atomic clocks.

Abstract

The non-equilibrium-steady state (NEST) for photons in a cavity is investigated theoretically. The NEST is caused by different parts of the cavity being at distinct temperatures or by temperature gradients. By using a rate equation based on the Lindblad equation, we derive an analytic expression for the steady-state distribution of the photon spectrum. We predict differences between the non-equilibrium steady state and a fit to the black-body spectrum calculated via Planck's law with an effective temperature. For two bodies of similar size at two temperatures which differ by a factor of two, the difference would be more than 10%. We also show that cavity resonances have a particularly large influence on the resulting non-equilibrium steady state of the photons. The investigation of thermal spectra in the presence of more than one temperature can be important for high-precision atomic clocks.