Differentiability of the Nonlocal-to-local Transition in Fractional Poisson Problems

IF 1 3区数学 Q1 MATHEMATICS Potential Analysis Pub Date : 2024-08-21 DOI:10.1007/s11118-024-10162-4

Sven Jarohs, Alberto Saldaña, Tobias Weth

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Abstract

Let $u_{s}$ denote a solution of the fractional Poisson problem

$$\begin{aligned} (-\Delta )^{s} u_{s} = f\quad \text { in }\Omega ,\qquad u_{s}=0\quad \text { on }{\mathbb {R}}^{N}\setminus \Omega , \end{aligned}$$

where $N\ge 2$ and $\Omega \subset {\mathbb {R}}^{N}$ is a bounded domain of class $C^{2}$. We show that the solution mapping $s\mapsto u_{s}$ is differentiable in $L^\infty (\Omega )$ at s = 1, namely, at the nonlocal-to-local transition. Moreover, using the logarithmic Laplacian, we characterize the derivative $\partial _{s} u_{s}$ as the solution to a boundary value problem. This complements the previously known differentiability results for s in the open interval (0, 1). Our proofs are based on an asymptotic analysis to describe the collapse of the nonlocality of the fractional Laplacian as s approaches 1. We also provide a new representation of $\partial _{s} u_{s}$ for s $\in (0,1)$ which allows us to refine previously obtained Green function estimates.

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分数泊松问题中的非局部到局部转变的可微分性

让 $u_{s}\ 表示分数泊松问题的解 $$\begin{aligned} (-\Delta )^{s} u_{s} = f\quad \text { in }\Omega 、\quad u_{s}=0/quad text { on }{\mathbb {R}}^{N}setminus \Omega , \end{aligned}$$ 其中 \(N\ge 2$ 和 $\Omega \subset {\mathbb {R}}^{N}$ 是类$C^{2}$的有界域。我们证明在 s = 1 时，即在非局部到局部的转换处，解映射 $s\mapsto u_{s}$ 在 $L^\infty (\Omega )$ 中是可微分的。此外，利用对数拉普拉斯，我们将导数 $\partial _{s} u_{s}$ 描述为边界值问题的解。这补充了之前已知的开放区间（0，1）中 s 的可微性结果。我们的证明基于渐近分析，描述了当 s 接近 1 时分数拉普拉奇非局部性的崩溃。我们还为 s $\in (0,1)$ 提供了 $\partial _{s} u_{s}$ 的新表示，这使我们能够完善之前得到的格林函数估计。

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来源期刊

Potential Analysis 数学-数学

CiteScore

2.20

自引率

9.10%

发文量

审稿时长

>12 weeks

期刊介绍： The journal publishes original papers dealing with potential theory and its applications, probability theory, geometry and functional analysis and in particular estimations of the solutions of elliptic and parabolic equations; analysis of semi-groups, resolvent kernels, harmonic spaces and Dirichlet forms; Markov processes, Markov kernels, stochastic differential equations, diffusion processes and Levy processes; analysis of diffusions, heat kernels and resolvent kernels on fractals; infinite dimensional analysis, Gaussian analysis, analysis of infinite particle systems, of interacting particle systems, of Gibbs measures, of path and loop spaces; connections with global geometry, linear and non-linear analysis on Riemannian manifolds, Lie groups, graphs, and other geometric structures; non-linear or semilinear generalizations of elliptic or parabolic equations and operators; harmonic analysis, ergodic theory, dynamical systems; boundary value problems, Martin boundaries, Poisson boundaries, etc.