{"title":"Bourgain–Brezis–Mironescu-Type Characterization of Inhomogeneous Ball Banach Sobolev Spaces on Extension Domains","authors":"Chenfeng Zhu, Dachun Yang, Wen Yuan","doi":"10.1007/s12220-024-01737-z","DOIUrl":null,"url":null,"abstract":"<p>Let <span>\\(\\{\\rho _\\nu \\}_{\\nu \\in (0,\\nu _0)}\\)</span> with <span>\\(\\nu _0\\in (0,\\infty )\\)</span> be a <span>\\(\\nu _0\\)</span>-radial decreasing approximation of the identity on <span>\\(\\mathbb {R}^n\\)</span>, <span>\\(X(\\mathbb {R}^n)\\)</span> a ball Banach function space satisfying some extra mild assumptions, and <span>\\(\\Omega \\subset \\mathbb {R}^n\\)</span> a <span>\\(W^{1,X}\\)</span>-extension domain. In this article, the authors prove that, for any <i>f</i> belonging to the inhomogeneous ball Banach Sobolev space <span>\\({W}^{1,X}(\\Omega )\\)</span>, </p><span>$$\\begin{aligned} \\lim _{\\nu \\rightarrow 0^+} \\left\\| \\left[ \\int _\\Omega \\frac{|f(\\cdot )-f(y)|^p}{ |\\cdot -y|^p}\\rho _\\nu (|\\cdot -y|)\\,\\textrm{d}y \\right] ^\\frac{1}{p}\\right\\| _{X(\\Omega )}^p =\\frac{2\\pi ^{\\frac{n-1}{2}}\\Gamma (\\frac{p+1}{2})}{\\Gamma (\\frac{p+n}{2})} \\left\\| \\,\\left| \\nabla f\\right| \\,\\right\\| _{X(\\Omega )}^p, \\end{aligned}$$</span><p>where <span>\\(\\Gamma \\)</span> is the Gamma function and <span>\\(p\\in [1,\\infty )\\)</span> is related to <span>\\(X(\\mathbb {R}^n)\\)</span>. Using this asymptotics, the authors further establish a characterization of <span>\\(W^{1,X}(\\Omega )\\)</span> in terms of the above limit. To achieve these, the authors develop a machinery via using a method of the extrapolation and some recently found profound properties of <span>\\(W^{1,X}(\\mathbb {R}^n)\\)</span> to overcome those difficulties caused by that the norm of <span>\\(X(\\mathbb {R}^n)\\)</span> has no explicit expression and <span>\\(X(\\mathbb {R}^n)\\)</span> might not be translation invariant. This characterization has a wide range of generality and can be applied to various Sobolev-type spaces, such as Morrey [Bourgain–Morrey-type, weighted (or mixed-norm or variable), local (or global) generalized Herz, Lorentz, and Orlicz (or Orlicz-slice)] Sobolev spaces, which are all new. Particularly, when <span>\\(X(\\Omega ):=L^p(\\Omega )\\)</span> with <span>\\(p\\in (1,\\infty )\\)</span>, this characterization coincides with the celebrated results of J. Bourgain, H. Brezis, and P. Mironescu in 2001 and H. Brezis in 2002; moreover, this characterization is also new even when <span>\\(X(\\Omega ):=L^q(\\Omega )\\)</span> with both <span>\\(q\\in (1,\\infty )\\)</span> and <span>\\(p\\in [1,q)\\cup (q,\\frac{n}{n-1}]\\)</span>. In addition, the authors give several specific examples of <span>\\(W^{1,X}\\)</span>-extension domains as well as <span>\\(\\dot{W}^{1,X}\\)</span>-extension domains.</p>","PeriodicalId":501200,"journal":{"name":"The Journal of Geometric Analysis","volume":"5 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-07-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"The Journal of Geometric Analysis","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1007/s12220-024-01737-z","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Let \(\{\rho _\nu \}_{\nu \in (0,\nu _0)}\) with \(\nu _0\in (0,\infty )\) be a \(\nu _0\)-radial decreasing approximation of the identity on \(\mathbb {R}^n\), \(X(\mathbb {R}^n)\) a ball Banach function space satisfying some extra mild assumptions, and \(\Omega \subset \mathbb {R}^n\) a \(W^{1,X}\)-extension domain. In this article, the authors prove that, for any f belonging to the inhomogeneous ball Banach Sobolev space \({W}^{1,X}(\Omega )\),
where \(\Gamma \) is the Gamma function and \(p\in [1,\infty )\) is related to \(X(\mathbb {R}^n)\). Using this asymptotics, the authors further establish a characterization of \(W^{1,X}(\Omega )\) in terms of the above limit. To achieve these, the authors develop a machinery via using a method of the extrapolation and some recently found profound properties of \(W^{1,X}(\mathbb {R}^n)\) to overcome those difficulties caused by that the norm of \(X(\mathbb {R}^n)\) has no explicit expression and \(X(\mathbb {R}^n)\) might not be translation invariant. This characterization has a wide range of generality and can be applied to various Sobolev-type spaces, such as Morrey [Bourgain–Morrey-type, weighted (or mixed-norm or variable), local (or global) generalized Herz, Lorentz, and Orlicz (or Orlicz-slice)] Sobolev spaces, which are all new. Particularly, when \(X(\Omega ):=L^p(\Omega )\) with \(p\in (1,\infty )\), this characterization coincides with the celebrated results of J. Bourgain, H. Brezis, and P. Mironescu in 2001 and H. Brezis in 2002; moreover, this characterization is also new even when \(X(\Omega ):=L^q(\Omega )\) with both \(q\in (1,\infty )\) and \(p\in [1,q)\cup (q,\frac{n}{n-1}]\). In addition, the authors give several specific examples of \(W^{1,X}\)-extension domains as well as \(\dot{W}^{1,X}\)-extension domains.