On $L^\infty$ estimates for fully nonlinear partial differential equations

TL;DR

This paper develops sharp $L^ abla$ estimates for fully nonlinear PDEs on non-Kähler manifolds, extending previous results from the Kähler case and applying to a broad class of geometric and non-integrable structures.

Contribution

It introduces a novel comparison method using auxiliary Monge-Ampère equations for non-Kähler manifolds, applicable to various geometric settings and non-linear equations.

Findings

Provides sharp $L^ abla$ estimates for non-linear PDEs on non-Kähler manifolds.

Extends the method to open manifolds and non-integrable structures.

First general approach applicable to large classes of non-linear equations.

Abstract

Sharp $L^\infty$ estimates are obtained for general classes of fully non-linear PDE's on non-K\"ahler manifolds, complementing the theory developed earlier by the authors in joint work with F. Tong for the K\"ahler case. The key idea is still a comparison with an auxiliary Monge-Amp\`ere equation, but this time on a ball with Dirichlet boundary conditions, so that it always admits a unique solution. The method applies not just to compact Hermitian manifolds, but also to the Dirichlet problem, to open manifolds with a positive lower bound on their injectivity radii, to $(n-1)$ form equations, and even to non-integrable almost-complex or symplectic manifolds. It is the first method applicable in any generality to large classes of non-linear equations, and it usually improves on other methods when they happen to be available for specific equations.