Concentration of ground state solution for a fractional Hamiltonian Systems

Abstract

In this paper we are concerned with the existence of ground states solutions for the following fractional Hamiltonian systems \ arrayll -tDα∞(-∞Dαt u(t)) - λ L(t)u(t)+∇ W(t,u(t))=0,\\[0.1cm] u ∈ Hα (R,Rn), array .(FHS)λ where α∈ (1/2,1), t∈ R, u∈ Rn, λ>0 is a parameter, L∈ C(R,Rn2) is a symmetric matrix for all t∈ R, W∈ C1(R × Rn,R) and ∇ W(t,u) is the gradient of W(t,u) at u. Assuming that L(t) is a positive semi-definite symmetric matrix for all t∈ R, that is, L(t) 0 is allowed to occur in some finite interval T of R, W(t,u) satisfies Ambrosetti-Rabinowitz condition and some other reasonable hypotheses, we show that (FHS)λ has a ground sate solution which vanishes on R T as λ ∞, and converges to u∈ Hα(R, Rn), where u∈ E0α is a ground state solution of the Dirichlet BVP for fractional systems on the finite interval T. Recent results are generalized and significantly improved.