Surfaces à courbure moyenne constante via les champs de spineurs / Constant mean curvature surfaces with spinor fields

Desmonts, Christophe

12 June 2015

Les travaux présentés dans cette thèse portent sur le rôle que peuvent jouer les différentes courbures extrinsèques d’une hypersurface dans l’étude de sa géométrie, en particulier dans le cas des variétés spinorielles. Dans un premier temps, nous nous intéressons au cas de la courbure moyenne et construisons une nouvelle famille de surfaces minimales non simplement connexes dans le groupe de Lie Sol3, en adaptant une méthode déjà utilisée par Daniel et Hauswirth dans Nil3 et utilisant les propriétés de l’application de Gauss d’une surface. Ensuite, nous démontrons le Théorème d’Alexandrov généralisé aux Hr-courbures dans l’espace euclidien Rn+1 et dans l’espace hyperbolique Hn+1 en testant un spineur adéquat dans des inégalités de type holographiques établies récemment par Hijazi, Montiel et Raulot. Grâce à ces inégalités, nous démontrons également l'Inégalité de Heintze-Karcher dans l'espace euclidien. Enfin, nous donnons des majorations extrinsèques de la première valeur propre de l’opérateur de Dirac des surfaces de S2 x S1(r) et des sphères de Berger Sb3 (τ) grâce aux restrictions de spineurs ambiants construits par Roth, et nous en caractérisons les cas d’égalité. / In this thesis we are interested in the role played by the extrinsic curvatures of a hypersurface in the study of its geometry, especially in the case of spin manifolds. First, we focus our attention on the mean curvature and construct a new family of non simply connected minimal surfaces in the Lie group Sol3, by adapting a method used by Daniel and Hauswirth in Nil3 based on the properties of the Gauss map of a surface. Then we give a new spinorial proof of the Alexandrov Theorem extended to all Hr-curvatures in the euclidean space Rn+1 and in the hyperbolic space Hn+1, using a well-chosen test-spinor in the holographic inequalities recently obtained by Hijazi, Montiel and Raulot. These inequalities lead to a new proof of the Heintze-Karcher Inequality as well. Finally we use restrictions of particular ambient spinor fields constructed by Roth to give some extrinsic upper bounds for the first nonnegative eigenvalue of the Dirac operator of surfaces immersed into S2 x S1(r) and into the Berger spheres Sb3 (τ), and we describe the equality cases.

Géométrie riemannienne

Géométrie spinorielle

Hypersurfaces

Surfaces minimales

Hr-Courbure

Opérateur de Dirac

Spectre

Théorème d'Alexandrov

Riemannian geometry

Spin geometry

Hypersurfaces

Minimal surfaces

Hr-Curvature

Dirac operator

Spectrum

Alexandrov Theorem

516.373

516.362

O teorema de Alexandrov / The theorem of Alexandrov.

Silva Neto, Gregorio Manoel da

04 August 2009

The goal of this dissertation is to present a R. Reilly's demonstration of the theorem of Alexandrov . The theorem states that The only compact hypersurfaces, conected, of constant mean curvature, immersed in Euclidean space are spheres. The theorem of Alexandrov was proved by A. D. Alexandrov in the article Uniqueness Theorems for Surfaces in the Large V, published in 1958 by Vestnik Leningrad University, volume 13, number 19, pages 5 to 8. In his demonstration, Alexandrov used the famous Principle of tangency, introduced by him in that article. In the year 1962, M. Obata shown in Certain Conditions for a Riemannian Manifold to be isometric With the Sphere, published by the Journal of Mathematical Society of Japan, volume 14, pages 333 to 340, that a Riemannian Manifold M, compact, connected and without boundary, is isometric to a sphere, since the Ricci curvature of M satisfies certain lower bound. This theorem solves the problem of finding manifolds that reach equality in the estimate of Lichnerowicz for the first eigenvalue. In 1977, R. Reilly, in the article Applications of the Hessian operator in a Riemannian Manifold, published in Indianna University Mathematical Journal, volume 23, pages 459 to 452, showed a generalization of the Obata theorem for compact manifolds with boundary. As an example of the technique developed in this demonstration, he presents a new demonstration of the theorem of Alexandrov. This demonstration, as well as the techniques involved are the object of study of this work. / Conselho Nacional de Desenvolvimento Científico e Tecnológico / O objetivo desta dissertação é apresentar uma demonstração de R. Reilly para o Teorema de Alexandrov. O teorema estabelece que As únicas hipersuperfícies compactas, conexas, de curvatura média constante, mergulhadas no espaço Euclidiano são as esferas. O teorema de Alexandrov foi provado por A. D. Alexandrov no artigo Uniqueness Theorems for Surfaces in the Large V, publicado em 1958 pela Vestnik Leningrad University, volume 13, número 19, páginas 5 a 8. Em sua demonstração, Alexandrov usou o famoso Princípio de Tangência, introduzido por ele no citado artigo. No ano de 1962, M. Obata demonstrou em Certain Conditions for a Riemannian Manifold to be Isometric With a Sphere, publicado pelo Journal of Mathematical Society of Japan, volume 14, páginas 333 a 340, que uma variedade Riemanniana M, compacta, conexa e sem bordo, é isométrica a uma esfera, desde que a curvatura de Ricci de M satisfaça determinada limitação inferior. Este teorema resolve o problema de encontrar as variedades que atingem a igualdade na estimativa de Lichnerowicz para o primeiro autovalor. Em 1977, R. Reilly, no artigo Applications of the Hessian Operator in a Riemannian Manifold, publicado no Indianna University Mathematical Journal, volume 23, páginas 459 a 452, demonstrou uma generalização do Teorema de Obata para variedades compactas com bordo. Como exemplo da técnica desenvolvida nesta demonstração, ele apresenta uma nova demonstração do Teorema de Alexandrov. Esta demonstração, bem como as técnicas envolvidas, são o objeto de estudo deste trabalho.

Geometria diferencial

Laplaciano

Hipersuperfícies

Curvatura média

Curvatura de Ricci

Alexandrov, teorema de

Obata, teorema de

Variedade riemanniana compacta

Differential geometry

Laplacian

Hypersurfaces

Mean curvature

Ricci Curvature

Alexandrov, theorem of

Obata, theorem of

Compact riemannian manifolds