Monotonicity of solutions for fractional equations with De Giorgi type nonlinearities

TL;DR

This paper introduces a new sliding method for fractional Laplacian equations, establishing monotonicity of solutions through novel maximum principles and integral estimates, advancing the analysis of nonlinear fractional PDEs.

Contribution

The paper develops a new sliding method for fractional Laplacian equations, including key principles and inequalities, to prove solution monotonicity.

Findings

Established maximum principles in bounded and unbounded domains.

Derived a new inequality for fractional Laplacian estimates.

Proved monotonicity of solutions for fractional equations.

Abstract

In this paper, we develop a sliding method for the fractional Laplacian. We first obtain the key ingredients needed in the sliding method either in a bounded domain or in the whole space, such as narrow region principles and maximum principles in unbounded domains. Then using semi-linear equations involving the fractional Laplacian in both bounded domains and in the whole space, we illustrate how this new sliding method can be employed to obtain monotonicity of solutions. Some new ideas are introduced. Among which, one is to use Poisson integral representation of $s$-subharmonic functions in deriving the maximum principle, the other is to estimate the singular integrals defining the fractional Laplacians along a sequence of approximate maximum points by using a generalized average inequality. We believe that this new inequality will become a useful tool in analyzing fractional equations.