New Perspectives On the Relevance of Gravitation for the Covariant Description of Electromagnetically Polarizable Media

TL;DR

This paper develops a covariant framework for describing electromagnetic properties of magneto-electric media in gravitational fields, linking geometric, energetic, and material aspects with experimental implications.

Contribution

It introduces a self-adjoint constitutive tensor for inhomogeneous, anisotropic media in arbitrary motion and explores invariant characterizations of magneto-electric media.

Findings

Formulated a covariant constitutive tensor for complex media.

Linked stress-energy-momentum tensors to spacetime symmetries.

Discussed experimental relevance in non-inertial and gravitational environments.

Abstract

Electromagnetic properties of a simple polarisable medium may be parameterised in terms of a constitutive tensor whose properties can in principle be determined by experiments in non-inertial (accelerating) frames and in the presence of weak but variable gravitational fields. After establishing some geometric notation, discussion is given to basic concepts of stress, energy and momentum in the vacuum where the useful notion of a drive form is introduced in order to associate the conservation of currents involving the flux of energy, momentum and angular momentum with spacetime isometries. The definition of the stress-energy-momentum tensor is discussed with particular reference to its symmetry based on its role as a source of relativistic gravitation. General constitutive properties of material continua are formulated in terms of spacetime tensors including those that describe magneto-electric phenomena in moving media. This leads to a formulation of a self-adjoint constitutive tensor describing, in general, inhomogeneous, anisotropic, magneto-electric bulk matter in arbitrary motion. The question of an invariant characterisation of intrinsically magneto-electric media is explored. An action principle is established to generate the phenomenological Maxwell system and the use of variational derivatives to calculate stress-energy-momentum tensors is discussed in some detail. The relation of this result to tensors proposed by Abraham and others is discussed in the concluding section where the relevance of the whole approach to experiments on matter in non-inertial environments with variable gravitational and electromagnetic fields is stressed.