Aspects of Quasi-local energy for gravity coupled to gauge fields

Abstract

We study the aspects of quasi-local energy associated with a 2-surface bounding a space-like domain of a physical 3+1 dimensional spacetime in the regime of gravity coupled to a gauge field. The Wang-Yau quasi-local energy together with an additional term arising due to the coupling of gravity to a gauge field constitutes the total energy (QLE) contained within the membrane =∂. We specialize in the Kerr-Newman family of spacetimes which contains a U(1) gauge field coupled to gravity and an outer horizon. Through explicit calculations, we show that the total energy satisfies a weaker version of a Bekenstein type inequality QLE> Q22R for large spherical membranes, Q is the charge and R is the radius of the membrane. Turning off the angular momentum (Reissner Nordstr\"om) yields QLE> Q22R for all constant radii membranes containing the horizon and in such case the charge factor appearing in the right-hand side exactly equals to that of Bekenstein's inequality. Moreover, we show that the total quasi-local energy monotonically decays from 2Mirr+VQ (Mirr is the irreducible mass, VQ is the electric potential energy) at the outer horizon to M (M is the ADM mass) at the space-like infinity under the assumption of a small angular momentum of the black hole.