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Si us plau utilitzeu sempre aquest identificador per citar o enllaçar aquest document: https://hdl.handle.net/2445/217109
Regularity theory for obstacle problems and boundary Harnack inequalities
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[eng] This thesis is dedicated to the study of elliptic and parabolic Partial Differential Equations,
both local and nonlocal. More specifically, this work concerns the regularity properties of
some obstacle problems.
Obstacle problems are prototypical examples of free boundary problems, that is, PDE
problems where the unknowns are not only a function, but also a subdivision of the domain
into different regions, and the PDE satisfied in each region is different.
Free boundary problems are a very active field of research. On the one hand, free
boundaries are a good model for interfaces in real-world settings, with applications in
Physics, Biology, Finance and Engineering. On the other hand, they have been a source of
interesting mathematical challenges, motivating the fine analysis of solutions to elliptic and
parabolic equations.
This Thesis is divided into two Parts. Part I is devoted to the study of several different
obstacle problems.
In Chapter 1, we study the obstacle problem for parabolic nonlocal operators, in the
supercritical regime s < 1/2. We establish the optimal C^{1,1} regularity of solutions,
which is surprisingly better than in the elliptic problem, and we also show that the free
boundary is globally C^{1,α}.
Our main difficulties are the lack of monotonicity formulas, and the supercritical scaling of the
equation, that is, the fact that the highest order of differentiation corresponds to the time
derivative.
Chapter 2 is devoted to the generic regularity properties of the free boundary in the thin
obstacle problem. Since there are many pathological examples of solutions to free boundary
problems, often the goal is instead of proving regularity for all solutions, proving regularity for
most solutions in an appropriate sense.
In our work, we show that, for one-parameter monotonous families of solutions, for almost
every solution, the free boundary is smooth outside of a set of codimension 2 + α (in the free
boundary). In particular, this means that in R^3 and R^4, the free boundary is generically
smooth.
We conclude Part I with Chapter 3, where we use a nonlocal analogue of the Bernstein
technique to establish semiconvexity estimates for a wide class of nonlinear nonlocal elliptic
and parabolic equations, including obstacle problems. As a consequence, we extend the
known regularity theory for nonlocal obstacle problems in the full space to problems in
bounded domains.
In Part II, we extend the boundary Harnack inequality to (local) elliptic and parabolic
equations with a right-hand side.
The boundary Harnack is a classical result that states that if u and v are positive harmonic
functions that vanish on part of the boundary of a regular enough domain, then u/v is
bounded and Hölder continuous up to the boundary. Boundary Harnack inequalities are used
in the proof of the smoothness of free boundaries in several obstacle problems, in the key
step of seeing that if a free boundary is flat Lipschitz, then it is C^{1,α}.
The goal of our work was to extend the regularity theory of obstacle problems to the fully
nonlinear setting. To do so, we developed boundary Harnack inequalities for equations in
non-divergence form with a right-hand side.
Chapter 4 concerns elliptic equations and Chapter 5 is about parabolic equations. The
techniques used are different. In the elliptic setting, it is enough to use barriers, scaling
arguments and a standard iteration to deduce the Hölder regularity of the quotient. However,
in the parabolic world, the proofs are much more involved and they are based on a delicate
contradiction-compactness argument.
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Matèries
Matèries (anglès)
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TORRES LATORRE, Clara. Regularity theory for obstacle problems and boundary Harnack inequalities. [consulta: 30 de novembre de 2025]. [Disponible a: https://hdl.handle.net/2445/217109]