Quasilocal Energy and Conserved Charges Derived from the Gravitational Action

TL;DR

This paper develops a Hamilton-Jacobi framework to define quasilocal energy and conserved charges in gravitational systems, linking geometric boundary properties to physical energy and momentum in a way consistent with known limits.

Contribution

It introduces a new method to compute quasilocal energy and conserved charges from the gravitational action using surface stress tensors and boundary geometry.

Findings

Quasilocal energy expressed via boundary mean curvature.

Agreement with ADM energy at spatial infinity.

Correct Newtonian limit for spherically symmetric spacetimes.

Abstract

The quasilocal energy of gravitational and matter fields in a spatially bounded region is obtained by employing a Hamilton-Jacobi analysis of the action functional. First, a surface stress-energy-momentum tensor is defined by the functional derivative of the action with respect to the three-metric on ${}^3B$, the history of the system's boundary. Energy density, momentum density, and spatial stress are defined by projecting the surface stress tensor normally and tangentially to a family of spacelike two-surfaces that foliate ${}^3B$. The integral of the energy density over such a two-surface $B$ is the quasilocal energy associated with a spacelike three-surface $\Sigma$ whose intersection with ${}^3B$ is the boundary $B$. The resulting expression for quasilocal energy is given in terms of the total mean curvature of the spatial boundary $B$ as a surface embedded in $\Sigma$. The quasilocal energy is also the value of the Hamiltonian that generates unit magnitude proper time translations on ${}^3B$ in the direction orthogonal to $B$. Conserved charges such as angular momentum are defined using the surface stress tensor and Killing vector fields on ${}^3B$. For spacetimes that are asymptotically flat in spacelike directions, the quasilocal energy and angular momentum defined here agree with the results of Arnowitt-Deser-Misner in the limit that the boundary tends to spatial infinity. For spherically symmetric spacetimes, it is shown that the quasilocal energy has the correct Newtonian limit, and includes a negative contribution due to gravitational binding.