The fully nonlinear Loewner-Nirenberg problem: Liouville theorems and counterexamples to local boundary estimates

Abstract

In this paper we give a complete classification of positive viscosity solutions w to conformally invariant equations of the form alignab* cases f(λ(-Aw)) = 12, λ(-Aw)∈ & in R+n w = 0 & on ∂R+n, cases align where Aw is the Schouten tensor of the metric gw = w-2|dx|2, ⊂Rn is a symmetric convex cone and f is an associated defining function satisfying standard assumptions. Solutions to ab yield metrics gw of negative curvature-type which are locally complete near ∂R+n. In particular, when (f,) = (σ1,1+), ab is the Loewner-Nirenberg problem in the upper half-space. More precisely, let μ+ denote the unique constant satisfying (-μ+, 1,…,1)∈∂. We show that when μ+ >1 (e.g. when = k+ for k<n2), the hyperbolic solution w(0)(x) := xn is the unique solution to ab. More surprisingly, we show that when μ+ ≤ 1 (e.g. when = k+ for k≥ n2), the solution set consists of a monotonically increasing one-parameter family \w(a)(xn)\a≥ 0, of which the hyperbolic solution w(0) is the minimal solution. In either case, solutions of ab are functions of xn. Our proof involves a novel application of the method of moving spheres for which we must establish new estimates and regularity near ∂R+n, followed by a delicate ODE analysis. As an application, we give counterexamples to local boundary C0 estimates on solutions to the fully nonlinear Loewner-Nirenberg problem when μ+ ≤ 1.