The Weil-Petersson gradient flow of renormalized volume and 3-dimensional convex cores

Abstract

In this paper, we use the Weil-Petersson gradient flow for renormalized volume to study the space CC(N;S,X) of convex cocompact hyperbolic structures on the relatively acylindrical 3-manifold (N;S). Among the cases of interest are the deformation space of an acylindrical manifold and the Bers slice of quasi-Fuchsian space associated to a fixed surface. To treat the possibility of degeneration along flow-lines to peripherally cusped structures, we introduce a surgery procedure to yield a surgered gradient flow that limits to the unique structure M geod ∈ CC(N;S,X) with totally geodesic convex core boundary facing S. Analyzing the geometry of structures along a flow line, we show that if VR(M) is the renormalized volume of M, then VR(M)-VR(M geod) is bounded below by a linear function of the Weil-Petersson distance d WP(∂c M, ∂c M geod), with constants depending only on the topology of S. The surgered flow gives a unified approach to a number of problems in the study of hyperbolic 3-manifolds, providing new proofs and generalizations of well-known theorems such as Storm's result that M geod has minimal volume for N acylindrical and the second author's result comparing convex core volume and Weil-Petersson distance for quasifuchsian manifolds.