Gravitational Self-force in a Radiation Gauge

Abstract

In this, the first of two companion papers, we present a method for finding the gravitational self-force in a modified radiation gauge for a particle moving on a geodesic in a Schwarzschild or Kerr spacetime. An extension of an earlier result by Wald is used to show the spin-weight 2 perturbed Weyl scalar (0 or 4) determines the metric perturbation outside the particle up to a gauge transformation and an infinitesimal change in mass and angular momentum. A Hertz potential is used to construct the part of the retarded metric perturbation that involves no change in mass or angular momentum from 0 in a radiation gauge. The metric perturbation is completed by adding changes in the mass and angular momentum of the background spacetime outside the radial coordinate r0 of the particle in any convenient gauge. The resulting metric perturbation is singular on the trajectory of the particle and discontinuous across the sphere r=r0. A mode-sum method can be used to renormalize the self-force, but the justification given in the published version of this paper sf2 referred to work by Sam Gralla gralla10 to justify the use of the renormalized self-force, and the radiation gauge we use does not satisfy the regularity conditions required by Gralla. Instead we show that the renormalized self-force, computed either from the retarded field for r>r0 or for r<r0 gives the correct equations of motion in a gauge smoothly related to a Lorenz gauge; and Pound et al. pmb13 argue that the average of the self-force obtained in the way described in our paper for r>r0 and for r<r0 gives the correct equation of motion for our gauge (what Pound et al. call the no-string gauge).