Geometric properties of a certain class of compact dynamical horizons in locally rotationally symmetric class II spacetimes

Abstract

In this paper we study the geometry of a certain class of compact dynamical horizons with a time-dependent induced metric in locally rotationally symmetric class II spacetimes. We first obtain a compactness condition for embedded 3-manifolds in these spacetimes, satisfying the weak energy condition, with non-negative isotropic pressure p. General conditions for a 3-manifold to be a dynamical horizon are imposed, as well as certain genericity conditions, which in the case of locally rotationally symmetric class II spacetimes reduces to the statement that `the weak energy condition is strictly satisfied or otherwise violated'. The compactness condition is presented as a spatial first order partial differential equation in the sheet expansion φ, in the form φ+(3/4)φ2-cK=0, where K is the Gaussian curvature of 2-surfaces in the spacetime and c is a real number parametrizing the differential equation, where c can take on only two values, 0 and 2. Using geometric arguments, it is shown that the case c=2 can be ruled out, and the S3 (3-dimensional sphere) geometry of compact dynamical horizons for the case c=0 is established. Finally, an invariant characterization of this class of compact dynamical horizons is also presented.