Concentration-compactness principle for Trudinger-Moser inequalities on Heisenberg Groups and existence of ground state solutions

Abstract

Let Hn=Cn×R be the n-dimensional Heisenberg group, Q=2n+2 be the homogeneous dimension of Hn. We extend the well-known concentration-compactness principle on finite domains in the Euclidean spaces of \ P. L. Lions to the setting of the Heisenberg group Hn. Furthermore, we also obtain the corresponding concentration-compactness principle for the Sobolev space HW1,Q( Hn) on the entire Heisenberg group Hn. Our results improve the sharp Trudinger-Moser inequality on domains of finite measure in Hn by Cohn and the second author [8] and the corresponding one on the whole space Hn by Lam and the second author [21]. All the proofs of the concentration-compactness principles in the literature even in the Euclidean spaces use the rearrangement argument and the Poly\'a-Szeg\"o inequality. Due to the absence of the Poly\'a-Szeg\"o inequality on the Heisenberg group, we will develop a different argument. Our approach is surprisingly simple and general and can be easily applied to other settings where symmetrization argument does not work. As an application of the concentration-compactness principle, we establish the existence of ground state solutions for a class of Q- Laplacian subelliptic equations on Hn with nonlinear terms f of maximal exponential growth ( α tQQ-1) as t→+∞.