Litcius/Paper detail

Second-order perturbations of the Schwarzschild spacetime: Practical, covariant, and gauge-invariant formalisms

Andrew Spiers, Adam Pound, Barry Wardell

2024Physical review. D/Physical review. D.32 citationsDOI

Abstract

High-accuracy gravitational-wave modeling demands going beyond linear, first-order perturbation theory. Particularly motivated by the need for second-order perturbative models of extreme-mass-ratio inspirals and black hole ringdowns, we present practical spherical-harmonic decompositions of the Einstein equation, Regge-Wheeler-Zerilli equations, and Teukolsky equation at second perturbative order in a Schwarzschild background. Our formulations are covariant on the $t\text{\ensuremath{-}}r$ plane and on the two-sphere, and we express the field equations in terms of gauge-invariant metric perturbations. In a companion Mathematica package, perturbationequations, we provide these invariant formulas as well as the analogous formulas in terms of raw, gauge-dependent metric perturbations. Our decomposition of the second-order Einstein equation, when specialized to the Lorenz gauge, was a key ingredient in recent second-order self-force calculations [Phys. Rev. Lett. 124, 021101 (2020); ibid. 127, 151102 (2021); ibid. 130, 241402 (2023)].

Topics & Concepts

Covariant transformationRotation formalisms in three dimensionsSpacetimeMathematical physicsSchwarzschild radiusGauge covariant derivativePhysicsInvariant (physics)Spherically symmetric spacetimeGauge theoryGauge (firearms)Theoretical physicsClassical mechanicsGauge fixingMathematicsQuantum field theory in curved spacetimeQuantum mechanicsGeometryQuantumGauge bosonQuantum gravityArchaeologyHistoryPulsars and Gravitational Waves ResearchAstrophysical Phenomena and ObservationsBlack Holes and Theoretical Physics