Geometric properties of Euclidean domains supporting trace inequalities

Abstract

We investigate the geometric behavior of τ(E) for bounded finite-perimeter sets E ⊂ Rn, where τ(E) is the trace constant introduced by Figalli--Maggi--Pratelli [Invent. Math. 2010]. This quantity is a key ingredient in proving a quantitative isoperimetric inequality with the optimal exponent. We first show that for every ε>0 one can find a bounded open set ⊂ Rn that is very close to the unit ball Bn in the sense that τ( Bn)>τ()>τ( Bn)-ε and P( Bn) C(n)ε, while at the same time the complement of has infinitely many connected components. Thus, τ() can be made arbitrarily close to τ( Bn) even when has highly intricate geometry. We then establish, under a mild additional hypothesis, the equivalence between a condition formulated in terms of τ and two classical criteria from the literature for open sets that admit trace inequalities. As a consequence, we obtain the John-type characterization of domains that support a trace inequality, assuming the ball separation property.