Large-Time Asymptotics for Heat and Fractional Heat Equations on the Lattice and General Finite Subgraphs

Abstract

In this paper, we study large-time asymptotics for heat and fractional heat equations in two discrete settings: the full lattice \( Zd\) and finite connected subgraphs with Dirichlet boundary condition. These results provide a unified discrete theory of long-time asymptotics for local and nonlocal diffusions. For \(d1\) and \(s∈(0,1]\), we consider on \( Zd\) the Cauchy problem \[ ∂t u+(-)s u=0, u(0)=u0∈ 1( Zd), \] and derive a precise first-order asymptotic expansion toward the lattice fractional heat kernel \(Gt(s)\). The main technical input is a pair of sharp translation-increment bounds for \(Gt(s)\): a pointwise estimate and an \(1\)-estimate. As consequences, under finite first moment we obtain the optimal decay rate \(t-1/(2s)\) in \(p\)-asymptotics (\(1 p∞\)), and we prove sharpness by explicit shifted-kernel examples. Without moment assumptions, we still establish convergence in the full \(1\)-class, and we show that no universal quantitative rate can hold in general. We also analyze fractional Dirichlet diffusion on finite connected subgraphs (restricted fractional setting, including \(s=1\) as the local case). In this finite-dimensional framework, solutions admit spectral decomposition and exhibit exponential large-time behavior governed by the principal eigenvalue and the spectral gap. In addition, we study positivity improving properties of the associated semigroups for both the lattice and Dirichlet evolutions.