22nd Geometry and Physics Colloquium
- Date: –16:00
- Location: Ångströmlaboratoriet, Lägerhyddsvägen 1 Häggsalen
- Lecturer: Marcos Mariño (Geneva U.) and James Sparks (Oxford U.)
- Contact person: Maxim Zabzine
Title 1: Resurgence and topological strings
Abstract 1: The theory of resurgence provides a precise and unified mathematical formulation of the non-perturbative sectors of a physical theory,
based solely on its perturbative expansion. In recent years it has been applied to topological quantum field theories and
topological strings, leading to many insights and results. For example, it has been found that, in many cases, the Stokes constants appearing
in resurgent analysis are related to BPS invariants. In this talk I will first review the relevant aspects of the
resurgence program, and then I will review recent progress on its implementation in topological string theory.
In particular, I will present exact results on multi-instanton amplitudes for the topological string on arbitrary Calabi-Yau manifolds,
and applications of these results to asymptotic problems in the theory of Gromov-Witten invariants.
Title 2: The geometry of black hole entropy functions
Abstract 2: One of the major successes of string theory has been a precise microstate counting of black hole entropy, at least for certain classes of
supersymmetric black holes in asymptotically flat spacetimes. Recently a growing body of similar work has been developed for black holes
in asymptotically Anti-de Sitter (AdS) spacetimes, where the microstate counting uses the AdS/CFT correspondence and a dual
field theory description.
After introducing the general topic, I will describe a certain Riemannian geometry associated to such black holes in AdS. This involves
a new type of PDE for a Kahler metric. While solving this PDE is in general a hard problem, I explain how solutions are critical points
of an "entropy function", which when evaluated on a solution is precisely the associated black hole entropy. Geometric techniques
then allow one to compute the entropy for various families of black holes, without solving the Einstein equations explicitly. I will conclude
by commenting on the relationship between this entropy function and the dual field theory.