Gibbons' conjecture for entire solutions of master equations

Abstract

In this paper, we establish a generalized version of Gibbons' conjecture in the context of the master equation equation* (∂t-)s u(x,t)=f(t,u(x,t)) \,\, in\,\, Rn×R. equation* We show that, for each t∈R, the bounded entire solution u(x,t) must be monotone increasing in one direction, and furthermore it is one-dimensional symmetric under certain uniform convergence assumption on u and an appropriate decreasing condition on f. These conditions are slightly weaker than their counter parts proposed in the original Gibbons' conjecture. To overcome the difficulties in proving the Gibbons' conjecture and the impediments caused by the strong correlation between space and time of fully fractional heat operator (∂t-)s, we introduce some new ideas and provide several new insights. More precisely, we first derive a weighted average inequality, which not only provides a straightforward proof for the maximum principle in bounded domains, but also plays a crucial role in further deducing the maximum principle in unbounded domains. Such average inequality and maximum principles are essential ingredients to carry out the sliding method, and then we apply this direct method to prove the Gibbons' conjecture in the setting of the master equation. It is important to note that the holistic approach developed in this paper is highly versatile, and will become useful tools in investigating various qualitative properties of solutions as well as in establishing the Gibbons' conjecture for a broad range of fractional elliptic and parabolic equations and systems.