Gravitomagnetic dynamical friction

Abstract

A supermassive black hole moving through a field of stars will gravitationally scatter the stars, inducing a backreaction force on the black hole known as dynamical friction. In Newtonian gravity, the axisymmetry of the system about the black hole's velocity v implies that the dynamical friction must be anti-parallel to v. However, in general relativity the black hole's spin S need not be parallel to v, breaking the axisymmetry of the system and generating a new component of dynamical friction similar to the Lorentz force F = qv × B experienced by a particle with charge q moving in a magnetic field B. We call this new force gravitomagnetic dynamical friction and calculate its magnitude for a spinning black hole moving through a field of stars with Maxwellian velocity dispersion σ, assuming that both v and σ are much less than the speed of light c. We use post-Newtonian equations of motion accurate to O(v3/c3) needed to capture the effect of spin-orbit coupling and also include direct stellar capture by the black hole's event horizon. Gravitomagnetic dynamical friction will cause a black hole with uniform speed to spiral about the direction of its spin, similar to a charged particle spiraling about a magnetic field line, and will exert a torque on a supermassive black hole orbiting a galactic center, causing the angular momentum of this orbit to slowly precess about the black-hole spin. As this effect is suppressed by a factor (σ/c)2 in nonrelativistic systems, we expect it to be negligible in most astrophysical contexts but provide this calculation for its theoretical interest and potential application to relativistic systems.