On Poincar\'e-Sobolev level involving fractional GJMS operators on hyperbolic space

Abstract

This paper is devoted to a qualitative analysis of the Poincar\'e--Sobolev level associated with the fractional GJMS operators \(Ps\) \((s∈(0, n2) N)\) on the hyperbolic space \( Hn\). In contrast to the integer-order case, when \(s N\) the operator \(Ps\) does not enjoy the conformal covariance that allows one, in the upper half-space or ball model, to relate it to the Euclidean fractional Laplacian \((-)s\); this link is crucial for importing Euclidean theory. We therefore introduce \(Ps\) (\(s>0\)), which is conformally related to \((-)s\). Our purpose in the paper is to analyze the monotonicity, attainability, and strict-gap regions of the Poincar\'e--Sobolev levels associated with \(Ps\) and \(Ps\). First, we reinterpret the Brezis--Nirenberg problem through the lens of Poincar\'e--Sobolev levels, connecting earlier results for the Euclidean Laplacian and for operators \(Pk\) on \( Hn\) with integer \(k∈(0, n2)\). We then establish new, explicit lower bounds for the Hardy term in fractional Hardy--Sobolev--Maz'ya inequalities involving both \(Ps\) and \(Ps\). By applying the concentration--compactness principle together with a detailed analysis of the strict-gap regions for the Poincar\'e--Sobolev levels, we prove the existence of solutions to the Brezis--Nirenberg problem on \( Hn\) for both operators. Finally, combining the Hardy lower bounds with criteria for attainability, we obtain a complete characterization of the Poincar\'e--Sobolev levels \(Hn,s\) and \( Hn,s\).