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 \begin{align}\label{ab}\tag{$*$} \begin{cases} f(\lambda(-A_w)) = \frac{1}{2}, \quad \lambda(-A_w)\in\Gamma & \text{in }\mathbb{R}+n \newline w = 0 & \text{on }\partial\mathbb{R}+n, \end{cases} \end{align} where $A_w$ is the Schouten tensor of the metric $g_w = w{-2}|dx|2$, $\Gamma\subset\mathbb{R}n$ is a symmetric convex cone and $f$ is an associated defining function satisfying standard assumptions. Solutions to \eqref{ab} yield metrics $g_w$ of negative curvature-type which are locally complete near $\partial\mathbb{R}+n$. In particular, when $(f,\Gamma) = (\sigma_1,\Gamma_1+)$, \eqref{ab} is the Loewner-Nirenberg problem in the upper half-space. More precisely, let $\mu\Gamma+$ denote the unique constant satisfying $(-\mu_\Gamma+, 1,\dots,1)\in\partial\Gamma$. We show that when $\mu_\Gamma+ >1$ (e.g. when $\Gamma = \Gamma_k+$ for $k<\frac{n}{2}$), the hyperbolic solution $w{(0)}(x) := x_n$ is the unique solution to \eqref{ab}. More surprisingly, we show that when $\mu_\Gamma+ \leq 1$ (e.g. when $\Gamma = \Gamma_k+$ for $k\geq \frac{n}{2}$), the solution set consists of a monotonically increasing one-parameter family ${w{(a)}(x_n)}_{a\geq 0}$, of which the hyperbolic solution $w{(0)}$ is the minimal solution. In either case, solutions of \eqref{ab} are functions of $x_n$. Our proof involves a novel application of the method of moving spheres for which we must establish new estimates and regularity near $\partial\mathbb{R}+n$, 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 $\mu\Gamma+ \leq 1$.
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