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Elliptic theory in domains with boundaries of mixed dimension / Guy David, Joseph Feneuil & Svitlana Mayboroda.
Math/Physics/Astronomy Library QA1 .A85 v.442
Available
Math/Physics/Astronomy Library QA3 .L282 1968/1969-2019/2021
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LIBRA QA3 .L282 no.901 (1980/1981)
Available from offsite location
Math/Physics/Astronomy Library QA1 .A85 1,4-6,9-11,13-15,18-35,38-68,71-91,94-95,97-99,101-103/104,107/108-115,117-118,123-132, 135-144,147-160,163-178,181-258,261-370,372-393,400-404,406-425,427-462
Mixed Availability
- Format:
- Book
- Author/Creator:
- David, Guy, 1957- author.
- Feneuil, J., 1988- author.
- Mayboroda, Svitlana, 1981- author.
- Series:
- Astérisque ; 0303-1179 442.
- Astérisque, 0303-1179 ; 442
- Language:
- English
- French
- Subjects (All):
- Differential equations, Elliptic.
- Boundary value problems.
- Physical Description:
- vi, 139 pages ; 24 cm.
- Place of Publication:
- Paris, France : Société mathématique de France, 2023.
- Language Note:
- Abstract also in French.
- Summary:
- "Take an open domain Ω ⊂ R n whose boundary may be composed of pieces of different dimensions. For instance, Ω can be a ball on R 3 , minus one of its diameters D, or Ω ⊂ R 3 could be a so-called saw-tooth domain, with a boundary consisting of pieces of 1-dimensional curves intercepted by 2-dimensional spheres. It could also be a domain with a fractal (or partially fractal) boundary. Under appropriate geometric assumptions, such as the existence of doubling measures on Ω and ∂Ω with appropriate size conditions, we construct a class of degenerate elliptic operators L adapted to the geometry, and establish key estimates of elliptic theory associated to those operators. This includes boundary Poincaré and Harnack inequalities, maximum principle, and Hölder continuity of solutions at the boundary. We introduce Hilbert spaces naturally associated to the geometry, construct appropriate trace and extension operators, and use them to define weak solutions to Lu = 0. Then we prove De Giorgi-Nash-Moser estimates inside Ω and on the boundary, solve the Dirichlet problem and thus construct an elliptic measure ω L associated to L. We construct Green functions and use them to prove a comparison principle and the doubling property for ω L. Since our theory emphasizes measures, rather than the geometry per se, the results are new even in the classical setting of a half-plane R 2 + when the boundary ∂R 2 + = R is equipped with a doubling measure µ singular with respect to the Lebesgue measure on R. Finally, the present paper provides a generalization of the celebrated Caffarelli-Sylvestre extension operator from its classical setting of R n+1 + to general open sets, and hence, an extension of the concept of fractional Laplacian to Ahlfors regular boundaries and beyond"--Abstract.
- Contents:
- Motivation and a general overview of the main results
- Our assumptions
- Some examples where our assumptions hold
- The definition of the space W
- The access cones and their properties
- The Trace Theorem
- Poincaré inequalities on the boundary
- The Extension Theorem
- Completeness of W and density of smooth functions
- . The localized versions Wr(E) of our energy space W
- Definitions of solutions and their properties
- Construction of the harmonic measure
- Bounded boundaries
- Green functions
- Comparison principle.
- Notes:
- Includes bibliographical references (pages [135]-139).
- ISBN:
- 9782856299746
- 2856299741
- OCLC:
- 1399544945
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