Liouville--Type Results for Infinity Elliptic Equations Involving Gradient and Hardy--H\'enon Nonlinearities
Abstract
In this paper we study Liouville-type properties for a class of degenerate elliptic equations driven by the fractional infinity Laplacian with nonlinear lower-order terms, \[ ∞βu - c\,H(u,∇ u) - λ\, f(|x|,u)=0 in Rn, \] where β∈[0,2], ∞β denotes the fractional infinity Laplace operator, and the nonlinearities H and f represent Hamiltonian and Hardy--H\'enon type effects, respectively. We extend the Liouville theory for the classical and normalized infinity Laplacian by establishing a new weighted comparison principle together with sharp local Lipschitz estimates for viscosity solutions. Our Liouville theorems are derived from precise growth conditions for bounded nonnegative solutions when f exhibits power-type behavior, i.e.\ f uγ. We also treat the exponential case f eu, for which the equation becomes strongly supercritical: under suitable assumptions on the growth of u at spatial infinity, only partial Liouville-type conclusions can be obtained. The analysis relies on radial reduction, barrier constructions, and refined comparison arguments. Altogether, the results provide a unified framework linking regularity, comparison principles, and Liouville-type phenomena for degenerate elliptic equations involving fractional infinity Laplacians and nonlinear lower-order effects.
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