Mathematics

Thermalization is the process through which a physical system evolves from an out-of-equilibrium state to a thermal state, where it can be described by statistical mechanics. In general, the thermalization process is rather complicate and it is not yet fully understood. This problem is known since the seminal work of Fermi, Pasta, Ulam, who studied numerically a simple one-dimensional model of a nonlinear crystal.

Description
Derived algebraic geometry is the natural setting in which mathematicians can study
deformation theory of schemes, moduli spaces, and highly singular objects employing the
ideas and the technical machinery of homological and categorical algebra. In a broader
sense, it also provides a unifying theoretical and conceptual framework encompassing
simultaneously the worlds of algebraic geometry, algebraic topology, homotopy theory and
higher category theory.

Topic of the course
The course will focus on algebraic surfaces. The first part will concern smooth
ones, mostly following ”Complex Algebraic Surfaces” by Arnaud Beauville, while
the second part will focus on singular surfaces and their resolutions.
Formative objectives
In the first part of the course (8 lectures) the students will learn the basics of
the theory of algebraic surfaces. The main topics are
• Riemann-Roch theorem.

The course is an introduction to Poisson geometry. In the first part, we shall introduce the basic notions related to Poisson geometry and we shall prove some basic results as the Weinstein s plitting theorem and the existence of symplectic realization.

In the last part of the course, we shall introduce the basic notions about Lie algebroids and Lie groupoids and explain theire relationship with Poisson structures.

Syllabus

1st lecture: Poisson brackets. Linear Poisson brackets on the dual of a Lie algebra.

Mathematics of many-body quantum systems

The course will discuss rigorous methods for the study of many-body systems of importance in quantum statistical mechanics and in condensed matter physics. The focus will be on analytic techniques that allow to describe in a quantitative way the large scale behavior of physically relevant systems. Specifically, we will discuss the following topics.

Part 1: continuous symmetry breaking in quantum spin systems.

1. definition and basic properties of determinantal point processes;
2. short introduction to the theory of orthogonal polynomials;
3. unitary ensembles of random matrices.
4. Gaussian Unitary Ensemble. Semicircle law and local properties of the eigenvalues (sine-kernel and Airy-kernel processes). Asymptotic analysis of integrals. 

The aim of the course is to introduce the audience to the analytic theory of Dubrovin-Frobenius manifolds.

The theory of Frobenius manifolds was constructed by B. Dubrovin to formulate in geometrical terms the WDVV equations of associativity of 2D topological field theories.

It has links to many branches of mathematics, like singularity theory and reflection groups, algebraic and enumerative geometry, quantum cohomology, theory of isomonodromic deformations, boundary value problems and Painlevé equations, integrable systems and non-linear waves.