Rotational Vacuum Friction of Nonabsorbing Particles

Abstract

A nonabsorbing particle rotating in vacuum can lose angular momentum only by converting mechanical energy into electromagnetic radiation. Here, we develop a quantum theory of rotational vacuum friction for small lossless particles and show that axial symmetry qualitatively changes the leading dissipation channel. At zero temperature, the frictional torque scales as MΩ7 with rotation frequency \ Omega in anisotropic particles due to the emission of correlated photon pairs whose frequencies sum to 2Ω, while a contribution to the torque linear in \ Omega is found at finite temperature. In contrast, axisymmetric particles are protected against photon-assisted friction regardless of temperature.