The first variation of the matter energy-momentum tensor with respect to the metric, and its implications on modified gravity theories

Abstract

The first order variation of the matter energy-momentum tensor Tμ with respect to the metric tensor gα β plays an important role in modified gravity theories with geometry-matter coupling, and in particular in the f(R,T) modified gravity theory. We obtain the expression of the variation δ Tμ /δ gα β for the baryonic matter described by an equation given in a parametric form, with the basic thermodynamic variables represented by the particle number density, and by the specific entropy, respectively. The first variation of the matter energy-momentum tensor turns out to be independent on the matter Lagrangian, and can be expressed in terms of the pressure, the energy-momentum tensor itself, and the matter fluid four-velocity. We apply the obtained results for the case of the f(R,T) gravity theory, where R is the Ricci scalar, and T is the trace of the matter energy-momentum tensor, which thus becomes a unique theory, also independent on the choice of the matter Lagrangian. A simple cosmological model, in which the Hilbert-Einstein Lagrangian is generalized through the addition of a term proportional to Tn is considered in detail, and it is shown that it gives a very good description of the observational values of the Hubble parameter up to a redshift of z≈ 2.5.