Faculty of Physics University of Warsaw > Events > Seminars > String Theory Journal Club

String Theory Journal Club

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room 5.42, Pasteura 5 at 16:30

Neil Lambert (King's College London & IFT UW)

Pairs of membranes

(2,0) to 2 M2's

room 5.42, Pasteura 5 at 10:30

Leszek Hadasz (Uniwersytet Jagielloński)

Quantum Liouville field theory - a short review, part II

room 5.42, Pasteura 5 at 11:00

Leszek Hadasz (Uniwersytet Jagielloński)

Quantum Liouville field theory - a short review

room 5.42, Pasteura 5 at 11:00

Piotr Kucharski (IFT UW)

Knots, BPS states, and algebraic curves - part III

In this talk I will describe specific examples and exact results connected with previously introduced relation between BPS invariants and extremal A-polynomials, in particular quantum ones.

room 5.42, Pasteura 5 at 11:45

Piotr Kucharski (IFT UW)

Knots, BPS states, and algebraic curves - part II

In this talk I will describe a specific examples and exact results connected with previously introduced relation between BPS invariants and extremal A-polynomials. Our considerations will cover classical as well as quantum objects on both sides.

room 5.42, Pasteura 5 at 11:00

Piotr Kucharski (IFT UW)

Knots, BPS states, and algebraic curves

In this talk I will describe a relation between BPS states connected to a specific M-branes configuration and a new class of algebraic curves called extremal A-polynomials of a knot. The talk will also serve as an introduction for the next one which will be focused on quantum BPS invariants and quantum extremal A-polynomials.

room 5.42, Pasteura 5 at 11:00

Paweł Ciosmak (MIM UW)

Partition function in Yang-Mills theory and the moduli space of flat connections in dimension 2

Let \Sigma be a closed, oriented surface equipped with a Riemannian metric and let G be a compact, connected Lie group. For this data, we introduce the Migdal model, by defining a discrete partition function. It happens to be independent of the choice of the decomposition of the surface into polygons, thus being a good model for the infinite dimensional Yang-Mills integral. I will introduce also the moduli space of flat connections \mathcal{M}, which is the space of flat G-connection over \Sigma modulo the gauge transfomations. It can be equipped with a canonical symplectic form and its symplectic volume can be computed as a certain limit of the Yang-Mills partition function. Moreover there is a bijection between \mathcal{M} and the G-representations of the fundamental group of \Sigma.

room 5.42, Pasteura 5 at 11:00

Miłosz Panfil (IFT UW)

Integrability, Yang-Baxter equation and solvable models in statistical physics (part II)

After a short review, in the last week, of a relation between the Yang-Baxter equation and integrability, this time I will focus solely on the 2d statistical integrable models. I will show how the integrability allows for an exact computation of the partition function. I will follow a review article by Deguchi (cond-mat/0304309).

room 5.42, Pasteura 5 at 11:00

Kazunobu Maruyoshi (Imperial College, London)

A review of class S and S_k theories

I would review (N=2 supersymmetric) class S and (N=1 supersymmetric) class S_k theories in four dimensions, which are defined by compactification of N=(2,0) and N=(1,0) of particular type in six dimensions on a Riemann surface respectively, mostly focusing on the former one. We see properties of these classes, e.g. dualities, from the viewpoint of the compactified Riemann surface. References: 0904.2715, 1503.05159.

room 5.42, Pasteura 5 at 11:00

Miłosz Panfil (IFT UW)

Integrability, Yang-Baxter equation and solvable models in statistical physics

I will start with a concise overview of a notation of integrability and its relation to the Yang-Baxter equation in various physical contexts of 1d and 2d physics. In the second part I will focus on 2d statistical physics and show how integrability helps in exact computation of the partition function. The presented material is standard. I will provide some classical references during the seminar.

room 5.42, Pasteura 5 at 11:00

Masahide Manabe (IFT UW)

Quantum curves and topological recursion

Based on the relation between matrix model and 2d CFT, I will show how to construct an infinite family of quantum curves. I will also discuss that starting from the spectral curve an infinite family of quantum curves can be reconstructed by (a beta-deformed version of) the topological recursion.

room 5.42, Pasteura 5 at 13:30

Masahide Manabe (IFT UW)

An introduction to quantum curves via matrix model

I will review a relation between a (beta-deformed) matrix model and 2d CFT. Especially I will discuss that using this relation an infinite family of quantum curves can be naturally obtained. In the classical limit the quantum curves reduce to a (classical) spectral curve.

room 5.42, Pasteura 5 at 13:30

Piotr Sułkowski (IFT UW)

Quantum curves as singular vectors

A structure of Virasoro singular vectors behind quantum curves will be revealed.

room 5.42, Pasteura 5 at 11:00

Piotr Sułkowski (IFT UW)

(Towards new look at) Virasoro singular vectors

A construction and properties of Virasoro singular vectors will be reviewed, with prospects of presenting new relations between conformal field theory, matrix models, and quantum curves.

room 5.42, Pasteura 5 at 11:00

Junya Yagi (IFT UW)

Quiver gauge theories, TQFT and integrable lattice models, II

I will talk about my recent work on the connections among quiver gauge theories, TQFT and integrable lattice models (arXiv:1504.04055), and probably on further developments along these lines based on my ongoing projects with other people.

room 5.42, Pasteura 5 at 11:00

Junya Yagi (IFT UW)