A heat flow for the mean field equation on a finite graph

Abstract

Inspired by works of Cast\'eras (Pacific J. Math., 2015), Li-Zhu (Calc. Var., 2019) and Sun-Zhu (Calc. Var., 2020), we propose a heat flow for the mean field equation on a connected finite graph G=(V,E). Namely \arraylll ∂tφ(u)= u-Q+ eu∫Veudμ\\[1.5ex] u(·,0)=u0, array. where is the standard graph Laplacian, is a real number, Q:V→R is a function satisfying ∫VQdμ=, and φ:R→R is one of certain smooth functions including φ(s)=es. We prove that for any initial data u0 and any ∈R, there exists a unique solution u:V×[0,+∞)→R of the above heat flow; moreover, u(x,t) converges to some function u∞:V→R uniformly in x∈ V as t→+∞, and u∞ is a solution of the mean field equation u∞-Q+eu∞∫Veu∞dμ=0. Though G is a finite graph, this result is still unexpected, even in the special case Q 0. Our approach reads as follows: the short time existence of the heat flow follows from the ODE theory; various integral estimates give its long time existence; moreover we establish a Lojasiewicz-Simon type inequality and use it to conclude the convergence of the heat flow.