Dynamical laws of superenergy in General Relativity

TL;DR

This paper investigates the physical meaning of superenergy in General Relativity by orthogonally splitting Bel and Bel-Robinson tensors, deriving dynamical laws analogous to electromagnetic energy conservation.

Contribution

It provides a novel interpretation of superenergy tensors in gravity through a splitting procedure, establishing dynamical laws similar to electromagnetism's Poynting theorem.

Findings

Orthogonal splitting yields physical quantities like superenergy density and flux.

Derived equations are analogous to electromagnetic energy conservation laws.

Clarifies the physical role of superenergy in gravitational fields.

Abstract

The Bel and Bel-Robinson tensors were introduced nearly fifty years ago in an attempt to generalize to gravitation the energy-momentum tensor of electromagnetism. This generalization was successful from the mathematical point of view because these tensors share mathematical properties which are remarkably similar to those of the energy-momentum tensor of electromagnetism. However, the physical role of these tensors in General Relativity has remained obscure and no interpretation has achieved wide acceptance. In principle, they cannot represent {\em energy} and the term {\em superenergy} has been coined for the hypothetical physical magnitude lying behind them. In this work we try to shed light on the true physical meaning of {\em superenergy} by following the same procedure which enables us to give an interpretation of the electromagnetic energy. This procedure consists in performing an orthogonal splitting of the Bel and Bel-Robinson tensors and analysing the different parts resulting from the splitting. In the electromagnetic case such splitting gives rise to the electromagnetic {\em energy density}, the Poynting vector and the electromagnetic stress tensor, each of them having a precise physical interpretation which is deduced from the {\em dynamical laws} of electromagnetism (Poynting theorem). The full orthogonal splitting of the Bel and Bel-Robinson tensors is more complex but, as expected, similarities with electromagnetism are present. Also the covariant divergence of the Bel tensor is analogous to the covariant divergence of the electromagnetic energy-momentum tensor and the orthogonal splitting of the former is found. The ensuing {\em equations} are to the superenergy what the Poynting theorem is to electromagnetism. See paper for full abstract.