Existence and convergence of solutions to fractional pure critical exponent problems

Abstract

We study existence and convergence properties of least-energy symmetric solutions (l.e.s.s.) to the pure critical problem equation* (-)sus=|us|2s-2us, us∈ Ds0(), 2s:=2NN-2s, equation* where s is any positive number, is either RN or a smooth symmetric bounded domain, and Ds0() is the homogeneous Sobolev space. Depending on the kind of symmetry considered, solutions can be sign changing. We show that, up to a subsequence, a l.e.s.s. us converges to a l.e.s.s. ut as s goes to any t>0. In bounded domains, this convergence can be characterized in terms of an homogeneous fractional norm of order t-. A similar characterization is no longer possible in unbounded domains due to scaling invariance and an incompatibility with the functional spaces; to circumvent these difficulties, we use a suitable rescaling and characterize the convergence via cut-off functions. If t is an integer, these results describe in a precise way the nonlocal-to-local transition. Finally, we also include a nonexistence result of nontrivial nonnegative solutions in a ball for any s>1.