<p>We obtain the Kato square root property for coupled second-order elliptic systems in divergence form subject to mixed boundary conditions on an open and possibly unbounded set in <InlineEquation ID="IEq1"> <EquationSource Format="TEX">\(\mathbb {R}^n\)</EquationSource> <EquationSource Format="MATHML"><math> <msup> <mrow> <mi mathvariant="double-struck">R</mi> </mrow> <mi>n</mi> </msup> </math></EquationSource> </InlineEquation> under two simple geometric conditions: The Dirichlet boundary parts for the respective components are Ahlfors–David regular and a quantitative connectivity property in the spirit of locally uniform domains holds near the remaining Neumann boundary parts. In contrast with earlier work, our proof is not based on the first-order approach due to Axelsson–Keith–McIntosh but uses a second-order approach in the spirit of the original solution to the Kato square root problem on Euclidean space. This way, the proof becomes substantially shorter and technically less demanding.</p>

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A second-order approach to the Kato square root problem on open sets

  • Sebastian Bechtel,
  • Cody Hutcheson,
  • Timotheus Schmatzler,
  • Tolgahan Tasci,
  • Mattes Wittig

摘要

We obtain the Kato square root property for coupled second-order elliptic systems in divergence form subject to mixed boundary conditions on an open and possibly unbounded set in \(\mathbb {R}^n\) R n under two simple geometric conditions: The Dirichlet boundary parts for the respective components are Ahlfors–David regular and a quantitative connectivity property in the spirit of locally uniform domains holds near the remaining Neumann boundary parts. In contrast with earlier work, our proof is not based on the first-order approach due to Axelsson–Keith–McIntosh but uses a second-order approach in the spirit of the original solution to the Kato square root problem on Euclidean space. This way, the proof becomes substantially shorter and technically less demanding.