Mappings of least Dirichlet energy and their Hopf differentials

Abstract

The paper is concerned with mappings between planar domains having least Dirichlet energy. The existence and uniqueness (up to a conformal change of variables in the domain) of the energy-minimal mappings is established within the class H2(X, Y) of strong limits of homeomorphisms in the Sobolev space W1,2(X, Y), a result of considerable interest in the mathematical models of Nonlinear Elasticity. The inner variation leads to the Hopf differential hz hz dz dz and its trajectories. For a pair of doubly connected domains, in which X has finite conformal modulus, we establish the following principle: A mapping h ∈ H2(X, Y) is energy-minimal if and only if its Hopf-differential is analytic in X and real along the boundary of X. In general, the energy-minimal mappings may not be injective, in which case one observes the occurrence of cracks in X. Nevertheless, cracks are triggered only by the points in the boundary of Y where Y fails to be convex. The general law of formation of cracks reads as follows: Cracks propagate along vertical trajectories of the Hopf differential from the boundary of X toward the interior of X where they eventually terminate before making a crosscut.