English

The Kummer tensor density in electrodynamics and in gravity

General Relativity and Quantum Cosmology 2015-06-19 v2 High Energy Physics - Theory

Abstract

Guided by results in the premetric electrodynamics of local and linear media, we introduce on 4-dimensional spacetime the new abstract notion of a Kummer tensor density of rank four, Kijkl{\cal K}^{ijkl}. This tensor density is, by definition, a cubic algebraic functional of a tensor density of rank four Tijkl{\cal T}^{ijkl}, which is antisymmetric in its first two and its last two indices: Tijkl=Tjikl=Tijlk{\cal T}^{ijkl} = - {\cal T}^{jikl} = - {\cal T}^{ijlk}. Thus, KT3{\cal K}\sim {\cal T}^3, see Eq.(46). (i) If T\cal T is identified with the electromagnetic response tensor of local and linear media, the Kummer tensor density encompasses the generalized {\it Fresnel wave surfaces} for propagating light. In the reversible case, the wave surfaces turn out to be {\it Kummer surfaces} as defined in algebraic geometry (Bateman 1910). (ii) If T\cal T is identified with the {\it curvature} tensor RijklR^{ijkl} of a Riemann-Cartan spacetime, then KR3{\cal K}\sim R^3 and, in the special case of general relativity, K{\cal K} reduces to the Kummer tensor of Zund (1969). This K\cal K is related to the {\it principal null directions} of the curvature. We discuss the properties of the general Kummer tensor density. In particular, we decompose K\cal K irreducibly under the 4-dimensional linear group GL(4,R)GL(4,R) and, subsequently, under the Lorentz group SO(1,3)SO(1,3).

Keywords

Cite

@article{arxiv.1403.3467,
  title  = {The Kummer tensor density in electrodynamics and in gravity},
  author = {Peter Baekler and Alberto Favaro and Yakov Itin and Friedrich W. Hehl},
  journal= {arXiv preprint arXiv:1403.3467},
  year   = {2015}
}

Comments

54 pages, 6 figures, written in LaTex; improved version in accordance with the referee report

R2 v1 2026-06-22T03:26:38.198Z