Varying Newton constant, entropy and the black hole evaporation law

Abstract

In Einstein equations we represent the energy-momentum tensor as the one (Tμ ) of a fluid plus the cosmological term. We consider time-dependent Newton ``constant" G, the cosmological term and non-conserved Tμ. The Bianchi identity imposes a relation between the energy-momentum (non)conservation and the variation of G and . The covariant divergence ∇μTμ can be related to the first law of thermodynamics. For compact systems of mass M from the Bianchi identity we obtain a power-law relation G M-γ with γ depending on pressure or entropy. We discuss radiation and a mass loss described by the Stefan-Boltzmann law. In this formula we insert an expression for the black hole area and its temperature T. The Bianchi identity together with a formula for temperature and entropy S determines the index γ in the relation between the Newton constant G and the mass M. If the entropy S is defined by the equation dS=T-1dM then γ=1 (the same as for zero pressure). If the formula of Bekenstein-Hawking entropy holds true for time-dependent G then γ=23. We discuss consequences for the evaporation law of some modified expressions for the entropy appearing in effective models of gravity resulting from an interaction with matter fields. In particular, γ=1 leads to a constant evaporation temperature whereas γ>1 to a decreasing temperature and luminosity.