Project description

This research network is on random discrete structures, which are ubiquitous in many areas of modern mathematics, and are essential to describe a host of phenomena in mathematical physics. For instance they play a key role in our understanding of phase transitions, which describe how physical systems can undergo abrupt changes (as when water changes from liquid to solid state below 0C). 

We will in particular focus on a number of fundamental two-dimensional examples, including the celebrated dimer model and planar graphs. By combining probabilistic and combinatorial perspectives we will aim to answer some of the most basic questions about these models: How to enumerate them, either exactly or approximately? How can one describe their random geometry in the large scale limit? How to explain that these structures keep arising under different guises in different problems? Such questions also have deep connections to questions in mathematical physics, from topological phase transitions to Liouville quantum gravity, which we aim to investigate.  

Over the four year duration of the project we will open PhD and postdoc positions and aim to build an integrated community centered on these themes. This will be fueled by numerous joint activities such as reading groups, regular colloquia, summer school, etc.  Keep checking the news page in order to stay up to date, or sign up to our mailing list!


Subprojects

Nathanael Berestycki - P2

Random geometry of dimers and planar maps 

Michael Drmota - P3

Hidden limit theorems in random discrete structures with a Benjamini-Schramm limit

Ilse Fischer - P4

Systematic approaches to bijective proofs

Mihyun Kang - P5

Phase transitions in random combinatorial structures

Christian Krattenthaler - P6

Tiling Enumeration

Marcin Lis - P7

Dimers beyond planarity - phase transition and scaling limits

Benedikt Stufler - P8

Asymptotic enumeration and study of discrete structures

Fabio Toninelli - P9

Dimer model: dynamics and scaling limits