Triangle Seminars
Monday, 23 Oct 2023
Lonti: Supergravity a la Fin de Siecle
Neil Lambert
(KCL)
Abstract:
In these lectures we will provide a basic introduction to Supergravity as it arises in String Theory and M-Theory. We will start by introducing vielbeins and spin connections in order to construct supergravity actions. In the second lecture we will briefly introduce the maximal supergravity theories in ten and eleven-dimensions. We will briefly discuss special holonomy manifolds, explicitly construct BPS p-brane solutions and prove their non-perturbative stability. Time permitting we will discuss toroidal compactifications and U-duality.
I will assume basic MSc level material (Riemannian geometry, fermions and rigid supersymmetry). The lecture notes that will be provided are largely self-contained but the text book “Supergravity†by Freedman and van Proeyen contains more details.
This time, there will be two lectures (one in the morning and one in the afternoon), with pizza lunch in between them.
In these lectures we will provide a basic introduction to Supergravity as it arises in String Theory and M-Theory. We will start by introducing vielbeins and spin connections in order to construct supergravity actions. In the second lecture we will briefly introduce the maximal supergravity theories in ten and eleven-dimensions. We will briefly discuss special holonomy manifolds, explicitly construct BPS p-brane solutions and prove their non-perturbative stability. Time permitting we will discuss toroidal compactifications and U-duality.
I will assume basic MSc level material (Riemannian geometry, fermions and rigid supersymmetry). The lecture notes that will be provided are largely self-contained but the text book “Supergravity†by Freedman and van Proeyen contains more details.
This time, there will be two lectures (one in the morning and one in the afternoon), with pizza lunch in between them.
Posted by: andrea
Tuesday, 24 Oct 2023
From amplitudes to black hole encounters
📍 London
Rodolfo Russo and Carlo Heissenberg
(QMUL)
Abstract:
We will discuss how amplitudes can be used to efficiently derive classical
gravitational-wave observables characterizing black hole binary encounters.
This technique is very flexible and can be applied to General Relativity, but
also to its extensions and, in the spirit of Effective Field Theory, can be used
to describe compact objects beyond Schwarzschild black holes. We will briefly
discuss some recent applications to spinning black holes and to the subleading
Post-Minkowsian waveforms.
We will discuss how amplitudes can be used to efficiently derive classical
gravitational-wave observables characterizing black hole binary encounters.
This technique is very flexible and can be applied to General Relativity, but
also to its extensions and, in the spirit of Effective Field Theory, can be used
to describe compact objects beyond Schwarzschild black holes. We will briefly
discuss some recent applications to spinning black holes and to the subleading
Post-Minkowsian waveforms.
Posted by: QMUL2
Wednesday, 25 Oct 2023
Integrable Quantum Field Theories Perturbed by Irrelevant Operators
Olalla Castro Alvaredo
(City University of London)
Abstract:
In this talk I will review recent results co-authored with Stefano Negro, Fabio Sailis and István Szécsényi. In this project we have addressed the problem of how to compute correlation functions in integrable quantum field theories perturbed by irrelevant perturbations such as the operator TTbar. It has been known for some time that integrability is preserved under such perturbations even though the S-matrix is modified by a CDD factor. Therefore, it is natural to expect that matrix elements of local fields may be computed by employing the standard form factor program, which was developed for integrable quantum field theories in the 70s. By doing so we have found that the form factors of local and semi-local fields have a universal structure which we have identified. This gives rise to correlation functions with distinct convergence/divergence properties, depending on the sign of the perturbation. In the convergent regime we find that the correlation functions scale as power-laws at short distances, similar to standard integrable quantum field theories, but with powers that are no longer the conformal dimensions of some field. At the heart of our construction is a function called the minimal form factor, whose structure I will discuss in some detail.
In this talk I will review recent results co-authored with Stefano Negro, Fabio Sailis and István Szécsényi. In this project we have addressed the problem of how to compute correlation functions in integrable quantum field theories perturbed by irrelevant perturbations such as the operator TTbar. It has been known for some time that integrability is preserved under such perturbations even though the S-matrix is modified by a CDD factor. Therefore, it is natural to expect that matrix elements of local fields may be computed by employing the standard form factor program, which was developed for integrable quantum field theories in the 70s. By doing so we have found that the form factors of local and semi-local fields have a universal structure which we have identified. This gives rise to correlation functions with distinct convergence/divergence properties, depending on the sign of the perturbation. In the convergent regime we find that the correlation functions scale as power-laws at short distances, similar to standard integrable quantum field theories, but with powers that are no longer the conformal dimensions of some field. At the heart of our construction is a function called the minimal form factor, whose structure I will discuss in some detail.
Posted by: IC2
Thursday, 26 Oct 2023
Decomposition of 2d pure Yang-Mills and the Gross-Taylor string theory
📍 London
Eric Sharpe
(Virginia Tech.)
Abstract:
In this talk we will attempt to reconcile two different results on
two-dimensional pure Yang-Mills theory.
Specifically, we will discuss how the fact that 2d pure Yang-Mills is equivalent
to a disjoint union of theories, is related to the Gross-Taylor description
of 2d pure Yang-Mills as the target-space field theory of a string theory.
The Gross-Taylor picture can be understood by first rewriting the
Yang-Mills partition function (in a large N limit) as a sum of
correlation functions in Dijkgraaf-Witten theories for the symmetric group
S_n, and then interpreting those Dijkgraaf-Witten
correlation functions in terms of
branched covers, which leads to the string theory description.
We first observe that the decomposition of the pure Yang-Mills aligns
perfectly with decomposition of S_n Dijkgraaf-Witten theory, and then
discuss decomposition and the branched covers interpretation.
We encounter two puzzles, and to solve them, propose that the Gross-Taylor
string theory has a higher-form symmetry.
In this talk we will attempt to reconcile two different results on
two-dimensional pure Yang-Mills theory.
Specifically, we will discuss how the fact that 2d pure Yang-Mills is equivalent
to a disjoint union of theories, is related to the Gross-Taylor description
of 2d pure Yang-Mills as the target-space field theory of a string theory.
The Gross-Taylor picture can be understood by first rewriting the
Yang-Mills partition function (in a large N limit) as a sum of
correlation functions in Dijkgraaf-Witten theories for the symmetric group
S_n, and then interpreting those Dijkgraaf-Witten
correlation functions in terms of
branched covers, which leads to the string theory description.
We first observe that the decomposition of the pure Yang-Mills aligns
perfectly with decomposition of S_n Dijkgraaf-Witten theory, and then
discuss decomposition and the branched covers interpretation.
We encounter two puzzles, and to solve them, propose that the Gross-Taylor
string theory has a higher-form symmetry.
Posted by: QMW