Enriched Phenomenology in Extended Palatini Theories

Abstract

We show that extended theories of gravity with Lagrangian f(R,RμRμ) in the Palatini formulation possess a phenomenology much richer than the simpler f(R) or f(RμRμ) theories. In fact, we find that the scalars R and Q=RμRμ can be written as algebraic functions of the energy density and pressure of the energy momentum tensor. In the simpler cases of f(R) or f(RμRμ) theories, R and Q are just functions of the trace T of the energy-momentum tensor. As a result, in radiation dominated universes f(R) and f(RμRμ) theories exhibit the same dynamics as general relativity with an effective cosmological constant. This is not the case of f(R,RμRμ) models, in which R=R(,P) and Q=Q(,P) and, therefore, modified dynamics exists even for traceless sources.