Lambda-modules and holomorphic Lie algebroids / Lambda-modules et algébroïdes de Lie holomorphes

Tortella, Pietro

06 October 2011

La thèse est consacrée à la construction et à l'étude des espaces de modules des connexions holomorphes algébroïdes de Lie sont étudiés.On commence par une classification des faisceaux d'algèbres filtrées quasi-polynômiales sur une variété complexe lisse projective en termes d'algébroïdes de Lie holomorphes et de leurs classes de cohomologie. Cela permet de construire les espaces de modules de connexions holomorphes agébroïdes de Lie par le formalisme des Lambda-modules de Simpson.Par ailleurs, on étudie la théorie des déformations de telles connexions, et on calcule le germe de leur espace de modules dans le cas de rang deux, lorsque la variété de base est une courbe. / The thesis is concerned with the consturction and the sudy of moduli spaces of holomorphic Lie algebroid connections. It provides a classification of sheaves of almost polynomials filtered algebras on a smooth projective complex variety in terms of holomorphic Lie algebroids and their cohomology classes. This permits to build moduli spaces of holomorphic Lie agebroid connections via Simpson's formalism of Lambda-modules. Furthermore, the deformation theory of such connections is suried, and the germ of their moduli spaces in the rank two case is computed when the base variety is a curve.

Lambda-modules

512.55

Classifying Lambda-modules up to Isomorphism and Applications to Iwasawa Theory

January 2011

abstract: In Iwasawa theory, one studies how an arithmetic or geometric object grows as its field of definition varies over certain sequences of number fields. For example, let $F/\mathbb{Q}$ be a finite extension of fields, and let $E:y^2 = x^3 + Ax + B$ with $A,B \in F$ be an elliptic curve. If $F = F_0 \subseteq F_1 \subseteq F_2 \subseteq \cdots F_\infty = \bigcup_{i=0}^\infty F_i$, one may be interested in properties like the ranks and torsion subgroups of the increasing family of curves $E(F_0) \subseteq E(F_1) \subseteq \cdots \subseteq E(F_\infty)$. The main technique for studying this sequence of curves when $\Gal(F_\infty/F)$ has a $p$-adic analytic structure is to use the action of $\Gal(F_n/F)$ on $E(F_n)$ and the Galois cohomology groups attached to $E$, i.e. the Selmer and Tate-Shafarevich groups. As $n$ varies, these Galois actions fit into a coherent family, and taking a direct limit one obtains a short exact sequence of modules $$0 \longrightarrow E(F_\infty) \otimes(\mathbb{Q}_p/\mathbb{Z}_p) \longrightarrow \Sel_E(F_\infty)_p \longrightarrow \Sha_E(F_\infty)_p \longrightarrow 0 $$ over the profinite group algebra $\mathbb{Z}_p[[\Gal(F_\infty/F)]]$. When $\Gal(F_\infty/F) \cong \mathbb{Z}_p$, this ring is isomorphic to $\Lambda = \mathbb{Z}_p[[T]]$, and the $\Lambda$-module structure of $\Sel_E(F_\infty)_p$ and $\Sha_E(F_\infty)_p$ encode all the information about the curves $E(F_n)$ as $n$ varies. In this dissertation, it will be shown how one can classify certain finitely generated $\Lambda$-modules with fixed characteristic polynomial $f(T) \in \mathbb{Z}_p[T]$ up to isomorphism. The results yield explicit generators for each module up to isomorphism. As an application, it is shown how to identify the isomorphism class of $\Sel_E(\mathbb{Q_\infty})_p$ in this explicit form, where $\mathbb{Q}_\infty$ is the cyclotomic $\mathbb{Z}_p$-extension of $\mathbb{Q}$, and $E$ is an elliptic curve over $\mathbb{Q}$ with good ordinary reduction at $p$, and possessing the property that $E(\mathbb{Q})$ has no $p$-torsion. / Dissertation/Thesis / Ph.D. Mathematics 2011

Mathematics

elliptic curves

Iwasawa theory

Lambda modules