Comparison results for the p-torsional rigidity on convex domains

Abstract

For each open, bounded and convex domain Ω⊂ RD, D≥ 2, and each real number p>1, we denote by up the p-torsion function on Ω, i.e. the solution of the torsional creep problem Δpu=-1 in Ω, u=0 on ∂ Ω, where Δpu:=div( ∇ u p-2∇ u) is the p-Laplacian. Let Tp(Ω) be the p-torsional rigidity on Ω, defined as Tp( Ω) :=∫Ωupdx. Define T( p;Ω) := Ω p-1Tp( Ω) 1-p, where |Ω| stands for the Lebesgue measure of Ω. The main purpose of this paper is to compare the values of T(p;Ω) for bounded convex domains having different inradii. We prove that for any 0<a<b there exists a constant γD,p∈[1/D,1), depending only on the dimension D and the parameter p, such that T(p;Ωb)≤ T(p;Ωa), for all Ωa∈D(a), and Ωb∈D(b), if and only if γD,pb≥ a, where D(r) denotes the family of convex bounded domains in RD of inradius r. In addition, we discuss the asymptotic equality case, the limiting regimes p→ 1+ and p→∞, and the sharpness of our bounds on model families such as rectangles, orthotopes, ellipses, and triangles. We also derive a Saint-Venant type comparison result under additional geometric constraints, as a direct consequence of our main theorem.