Minimal doubling for small subsets in compact Lie groups

Abstract

We prove a sharp bound for the minimal doubling of a small measurable subset of a compact connected Lie group. Namely, let G be a compact connected Lie group of dimension dG, we show that for for all measurable subsets A, we have μG(A2) ≥ (2dG-dH - CμG(A)2dG-dH)μG(A) where dH is the maximal dimension of a proper closed subgroup H and C > 0 is a dimensional constant. This settles a conjecture of Breuillard and Green, and recovers and improves - with completely different methods - a recent result of Jing--Tran--Zhang corresponding to the case G=SO3(R). As is often the case, the above doubling inequality stems from a special case of general product-set estimates. We prove that for all ε >0 and for any pair of sufficiently small measurable subsets A,B a Brunn--Minkowski-type inequality holds: μG(AB)1dG-dH ≥ (1-ε)( μG(A)1dG-dH + μG(B)1dG-dH). Going beyond the scope of the Breuillard--Green conjecture, we prove a stability result asserting that the only subsets with close to minimal doubling are essentially neighbourhoods of proper subgroups i.e. of the form Hδ:=\g ∈ G: d(g,H)<δ\ where H denotes a proper closed subgroup of maximal dimension, d denotes a bi-invariant distance on G and δ >0. Our approach relies on a combination of two toolsets: optimal transports and its recent applications to the Brunn--Minkowski inequality, and the structure theory of compact approximate subgroups.