Hadamard's inequality in the mean

Abstract

Let Q be a Lipschitz domain in Rn and let f ∈ L∞(Q). We investigate conditions under which the functional In()=∫Q |∇ |n+ f(x)\,det ∇ \, dx obeys In ≥ 0 for all ∈ W01,n(Q,Rn), an inequality that we refer to as Hadamard-in-the-mean, or (HIM). We prove that there are piecewise constant f such that (HIM) holds and is strictly stronger than the best possible inequality that can be derived using the Hadamard inequality nn2| A|≤ |A|n alone. When f takes just two values, we find that (HIM) holds if and only if the variation of f in Q is at most 2nn2. For more general f, we show that (i) it is both the geometry of the `jump sets' as well as the sizes of the `jumps' that determine whether (HIM) holds and (ii) the variation of f can be made to exceed 2nn2, provided f is suitably chosen. Specifically, in the planar case n=2 we divide Q into three regions \f=0\ and \f= c\, and prove that as long as \f=0\ `insulates' \f= c\ from \f= -c\ sufficiently, there is c>2 such that (HIM) holds. Perhaps surprisingly, (HIM) can hold even when the insulation region \f=0\ enables the sets \f= c\ to meet in a point. As part of our analysis, and in the spirit of the work of Mielke and Sprenger (1998), we give new examples of functions that are quasiconvex at the boundary.