A covering theorem for singular measures in the Euclidean space

Abstract

We prove that for any singular measure μ on Rn it is possible to cover μ-almost every point with n families of Lipschitz slabs of arbitrarily small total width. More precisely, up to a rotation, for every δ>0 there are n countable families of 1-Lipschitz functions \fi1\i∈N,…, \fin\i∈N, fij:\xj=0\⊂Rn, and n sequences of positive real numbers \i1\i∈N,…, \in\i∈N such that, denoting xj the orthogonal projection of the point x onto \xj=0\ and Iij:=\x=(x1,…,xn)∈ Rn:fij( xj)-ij< xj< fij( xj)+ij\, it holds Σi,jij≤ δ and μ(Rni,jIij)=0. We apply this result to show that, if μ is not absolutely continuous, it is possible to approximate the identity with a sequence gh of smooth equi-Lipschitz maps satisfying h∞∫Rndet(∇ gh) dμ<μ(Rn). From this, we deduce a simple proof of the fact that every top-dimensional Ambrosio-Kirchheim metric current in Rn is a Federer-Fleming flat chain.