Quantum Torque on a Non-Reciprocal Body out of Thermal Equilibrium and Induced by a Magnetic Field of Arbitrary Strength

TL;DR

This paper derives an exact analytical expression for quantum torque experienced by a non-reciprocal body out of thermal equilibrium, induced by an arbitrary magnetic field, and explores its temperature-dependent behavior and resonance contributions.

Contribution

It extends previous models by including arbitrary magnetic field strength, providing a closed-form expression for quantum torque in non-reciprocal bodies under thermal non-equilibrium.

Findings

Torque persists at zero damping due to resonance modes.

High-temperature expansion separates spectral and resonance contributions.

Low-temperature behavior analyzed with magnetic field effects included.

Abstract

A stationary body that is out of thermal equilibrium with its environment, and for which the electric susceptibility is non-reciprocal, experiences a quantum torque. This arises from the spatially non-symmetric electrical response of the body to its interaction with the non-equilibrium thermal fluctuations of the electromagnetic field: the non-equilibrium nature of the thermal field fluctuations results in a net energy flow through the body, and the spatially non-symmetric nature of the electrical response of the body to its interaction with these field fluctuations causes that energy flow to be transformed into a rotational motion. We establish an exact, closed-form, analytical expression for this torque in the case that the environment is the vacuum and the material of the body is described by a damped oscillator model, where the non-reciprocal nature of the electric susceptibility is induced by an external magnetic field, as for magneto-optical media. We also generalise this expression to the context in which the body is slowly rotating. By exploring the high-temperature expansion of the torque, we are able to identify the separate contributions from the continuous spectral distribution of the non-reciprocal electric susceptibility, and from the resonance modes. In particular, we find that the torque persists in the limiting case of zero damping parameter, due to the contribution of the resonance modes. We also consider the low-temperature expansion of the torque. This work extends our previous consideration of this model to an external magnetic field of arbitrary strength, thereby including non-linear magnetic field effects.