Riesz transform and Hardy spaces related to elliptic operators having Robin boundary conditions on Lipschitz domains with their applications to optimal endpoint regularity estimates

IF 2.1 2区数学 Q1 MATHEMATICS

Calculus of Variations and Partial Differential Equations Pub Date : 2024-08-05 DOI:10.1007/s00526-024-02785-7

Dachun Yang, Sibei Yang, Yang Zou

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引用次数: 0

Abstract

Let $n\ge 2$ and $\Omega $ be a bounded Lipschitz domain of $\mathbb {R}^n$. Assume that $L_R$ is a second-order divergence form elliptic operator having real-valued, bounded, symmetric, and measurable coefficients on $L^2(\Omega )$ with the Robin boundary condition. In this article, via first obtaining the Hölder estimate of the heat kernels of $L_R$, the authors establish a new atomic characterization of the Hardy space $H^p_{L_R}(\Omega )$ associated with $L_R$. Using this, the authors further show that, for any given $p\in (\frac{n}{n+\delta _0},1]$,

$$\begin{aligned} H^p_z(\Omega )+L^\infty (\Omega )=H^p_{L_N}(\Omega )=H^p_{L_R}(\Omega )\subsetneqq H^p_{L_D}(\Omega )=H^p_r(\Omega ), \end{aligned}$$

where $H^p_{L_D}(\Omega )$ and $H^p_{L_N}(\Omega )$ denote the Hardy spaces on $\Omega $ associated with the corresponding elliptic operators respectively having the Dirichlet and the Neumann boundary conditions, $H^p_z(\Omega )$ and $H^p_r(\Omega )$ respectively denote the “supported type” and the “restricted type” Hardy spaces on $\Omega $, and $\delta _0\in (0,1]$ is the critical index depending on the operators $L_D$, $L_N$, and $L_R$. The authors then obtain the boundedness of the Riesz transform $\nabla L_R^{-1/2}$ on the Lebesgue space $L^{p}(\Omega )$ when $p\in (1,\infty )$ [if $p>2$, some extra assumptions are needed] and its boundedness from $H_{L_R}^{p}(\Omega )$ to $L^{p}(\Omega )$ when $p\in (0,1]$ or to $H^{p}_r(\Omega )$ when $p\in (\frac{n}{n+1},1]$. As applications, the authors further obtain the global regularity estimates, in $L^{p}(\Omega )$ when $p\in (0,p_0)$ and in $H^{p}_r(\Omega )$ when $p\in (\frac{n}{n+1},1]$, for the inhomogeneous Robin problem of $L_R$ on $\Omega $, where $p_0\in (2,\infty )$ is a constant depending only on n, $\Omega $, and the operator $L_R$. The main novelties of these results are that the range $(0,p_0)$ of p for the global regularity estimates in the scale of $L^p(\Omega )$ is sharp and that, in some sense, the space $X{:}{=}H^1_{L_R}(\Omega )$ is also optimal to guarantee both the boundedness of $\nabla L^{-1/2}_R$ from X to $L^1(\Omega )$ or to $H^1_r(\Omega )$ and the global regularity estimate $\Vert \nabla u\Vert _{L^{\frac{n}{n-1}} (\Omega ;\,\mathbb {R}^n)}\le C\Vert f\Vert _{X}$ for inhomogeneous Robin problems with C being a positive constant independent of both u and f.

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与 Lipschitz 域上具有 Robin 边界条件的椭圆算子相关的 Riesz 变换和 Hardy 空间及其在最佳端点正则估计中的应用

让 $n\ge 2$ 和 $\Omega $ 是 $\mathbb {R}^n$ 的有界 Lipschitz 域。假设$L_R$是一个二阶发散形式的椭圆算子，在$L^2(\Omega )$上具有实值、有界、对称和可测的系数，并具有 Robin 边界条件。在这篇文章中，通过首先获得 $L_R$ 热核的荷尔德估计，作者建立了与$L_R$ 相关的哈代空间 $H^p_{L_R}(\Omega )$ 的新的原子特征。利用这一点，作者进一步证明，对于任何给定的（p在（\frac{n}{n+\delta _0},1]\）中）、$$\begin{aligned} H^p_z(\Omega )+L^\infty (\Omega )=H^p_{L_N}(\Omega )=H^p_{L_R}(\Omega )\subsetneqq H^p_{L_D}(\Omega )=H^p_r(\Omega )、\end{aligned}$$其中（H^p_{L_D}(\Omega )）和（H^p_{L_N}(\Omega )）分别表示与相应的椭圆算子相关的 $\Omega $上的哈迪空间，它们分别具有迪里夏特和诺伊曼边界条件、$H^p_z(\Omega)$和(H^p_r(\Omega)\)分别表示$\Omega $上的 "支持型 "和 "限制型 "哈代空间，(\delta _0\in (0,1]\)是取决于算子$L_D$、$L_N$和$L_R$的临界指数。然后，当 $p\in (1,\infty )$ 时，作者得到了 Lebesgue 空间 $L^{p}(\Omega )$ 上 Riesz 变换 $\nabla L_R^{-1/2}$ 的有界性。[if （p>；2), some extra assumptions are needed] and its boundedness from $H_{L_R}^{p}(\Omega )$ to $L^{p}(\Omega )$ when $p\in (0,1]$ or to$H^{p}_r(\Omega )$ when $p\in (\frac{n}{n+1},1]$.作为应用，作者进一步得到了当 p\in (0,p_0)时在$L^{p}(\Omega )$中和当 p\in (\frac{n}{n+1}. 1]\)时在$H^{p}_r(\Omega )$中的全局正则估计、1]\) 时，对于 $L_R$ 在 $\Omega $ 上的不均匀罗宾问题，其中 $p_0\in (2,\infty )$ 是一个常数，只取决于 n、 $\Omega $ 和算子 $L_R$。这些结果的主要新颖之处在于，在尺度为 $L^p(\Omega )$ 的全局正则性估计中，p 的范围 $(0,p_0)$ 是尖锐的，而且在某种意义上，空间 $X{：}{=}H^1_{L_R}(\Omega )$ 也是最优的，既能保证从 X 到 $L^1(\Omega )$ 或者到 $H^1_r(\Omega )$ 的 $\Vert \nabla u\Vert _{L^{\frac{n}{n-1}} 的有界性，又能保证全局正则性估计的有界性。(\Omega ; \,\mathbb {R}^n)}\le C\Vert f\Vert _{X}$ for inhomogeneous Robin problems with C being a positive constant independent of both u and f.

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来源期刊

Calculus of Variations and Partial Differential Equations 数学-数学

CiteScore

3.30

自引率

4.80%

发文量

224

审稿时长

6 months

期刊介绍： Calculus of variations and partial differential equations are classical, very active, closely related areas of mathematics, with important ramifications in differential geometry and mathematical physics. In the last four decades this subject has enjoyed a flourishing development worldwide, which is still continuing and extending to broader perspectives. This journal will attract and collect many of the important top-quality contributions to this field of research, and stress the interactions between analysts, geometers, and physicists. The field of Calculus of Variations and Partial Differential Equations is extensive; nonetheless, the journal will be open to all interesting new developments. Topics to be covered include: - Minimization problems for variational integrals, existence and regularity theory for minimizers and critical points, geometric measure theory - Variational methods for partial differential equations, optimal mass transportation, linear and nonlinear eigenvalue problems - Variational problems in differential and complex geometry - Variational methods in global analysis and topology - Dynamical systems, symplectic geometry, periodic solutions of Hamiltonian systems - Variational methods in mathematical physics, nonlinear elasticity, asymptotic variational problems, homogenization, capillarity phenomena, free boundary problems and phase transitions - Monge-Ampère equations and other fully nonlinear partial differential equations related to problems in differential geometry, complex geometry, and physics.