Gravitational radiation reaction and second order perturbation theory

Abstract

A point particle of small mass m moves in free fall through a background vacuum spacetime metric gab and creates a first-order metric perturbation h1retab that diverges at the particle. Elementary expressions are known for the singular m/r part of h1retab and for its tidal distortion determined by the Riemann tensor in a neighborhood of m. Subtracting this singular part h1Sab from h1retab leaves a regular remainder h1Rab. The self-force on the particle from its own gravitational field adjusts the world line at O(m) to be a geodesic of gab+h1Rab. The generalization of this description to second-order perturbations is developed and results in a wave equation governing the second-order h2retab with a source that has an O(m2) contribution from the stress-energy tensor of m added to a term quadratic in h1retab. Second-order self-force analysis is similar to that at first order: The second-order singular field h2Sab subtracted from h2retab yields the regular remainder h2Rab, and the second-order self-force is then revealed as geodesic motion of m in the metric gab+h1R+h2R.