Geometry and Mathematical Physics

∙ Integrable systems in relation with differential, algebraic and symplectic geometry, as well as with the theory of random matrices, special functions and nonlinear waves, Frobenius manifolds • Deformation theory, moduli spaces of sheaves and of curves, in relation with supersymmetric gauge theories, strings, Gromov-Witten invariants, orbifolds and automorphisms
• Quantum groups, noncommutative Riemannian and spin geometry, applications to models in mathematical physics
• Mathematical methods of quantum mechanics
• Mathematical aspects of quantum Field Theory and String  Theory
• Symplectic geometry, sub-riemannian geometry 
• Geometry of quantum fields and strings

Mukai bundles on curves, K3 surfaces, and Fano 3-folds

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Mathematical Physics Seminar

Organizers

Matteo Gallone, Davide Guzzetti, Tamara Grava, Igor Krasovsky, Marcello Porta

Venue

SISSA Main Building, Wednesday 16:00-17:00, Room 136.

2023-2024 Mathematical Physics Seminar

Date	Speaker	Title
22 Nov 2023	Pierre Karim Emile Lazag (SISSA)	Hyperuniform determinantal point processes

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Hyperuniform determinantal point processes

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A tale of issues in determinantal ideals

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Towards Flag Ind-supermanifolds

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Introduction to nonperturbative methods for fermionic models

This course presents techniques used to rigorously approach the analysis of statistical mechanical systems of interacting fermions on a lattice.

Topics:

Universality and Critical phenomena
Gaussian integration, Feynman graphs and Linked Cluster Theorem
Grassmann variables and Grassmann Gaussian integration
Perturbation theory for Fermions using Grassmann variables
Brydges-Battle-Federbush formula with applications.

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Constructions of 4-manifolds

Description:

We will review several constructions of smooth four-dimensional manifolds that have proven useful to unveil inequivalent smooth structures.

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Introduction to topological quantum field theory

The course provides a brief introduction to Topological Field Theories as infinite dimensional generalisation of classical localisation formulae in equivariant cohomology. It starts with an introduction to these latter subjects (Duistermaat-Heckman theorem, equivariant cohomology and Atiyah-Bott formula) and their extension on supermanifolds. It then continues supersymmetric quantum mechanics and its relation with Morse theory, gradient flow lines and Morse-Smale-Witten complex.

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Topics in complex geometry

The aim of the course is to give an introduction to some topics of current interest in the globalgeometry of compact Kähler manifols.Part I – Basic notions. Hermitian and Kähler manifolds, harmonic theory, Kodaira Vanishing andEmbedding, Kempf-Ness Theorem, notions of canonical Kähler metrics.Some textbooks:

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3-dimensional mirror symmetry and elliptic cohomology

This is an advanced course that will explore connections between recent developments in geom- etry, mathematical physics and homotopy theory. Its format will be that of a working seminar. Mirror symmetry has been at the center stage of geometry for the last thirty years. It is a sophisticated dictionary relating the symplectic geometry of a variety X and the algebraic ge- ometry of its mirror Y , and vice versa.

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Mathematics