The n-body problem in General Relativity up to the second post-Newtonian order from perturbative field theory

TL;DR

This paper uses perturbative field theory methods to compute the effective Lagrangian for the n-body problem in general relativity up to the second post-Newtonian order, aiming to improve gravitational wave predictions.

Contribution

It introduces a perturbative approach from quantum field theory to calculate higher-order post-Newtonian corrections in the n-body problem, including an algorithm for automating these calculations.

Findings

Derived Feynman diagrams for n-body effective action at 2PN order.

Outlined an algorithm for automated higher-order calculations.

Progress towards computing gravitational interactions beyond current limits.

Abstract

Motivated by experimental probes of general relativity, we adopt methods from perturbative (quantum) field theory to compute, up to certain integrals, the effective lagrangian for its n-body problem. Perturbation theory is performed about a background Minkowski spacetime to O[(v/c)^4] beyond Newtonian gravity, where v is the typical speed of these n particles in their center of energy frame. For the specific case of the 2 body problem, the major efforts underway to measure gravitational waves produced by in-spiraling compact astrophysical binaries require their gravitational interactions to be computed beyond the currently known O[(v/c)^7]. We argue that such higher order post-Newtonian calculations must be automated for these field theoretic methods to be applied successfully to achieve this goal. In view of this, we outline an algorithm that would in principle generate the relevant Feynman diagrams to an arbitrary order in v/c and take steps to develop the necessary software. The Feynman diagrams contributing to the n-body effective action at O[(v/c)^6] beyond Newton are derived.