Towards a theory for the formation of sea stacks
Fowler, A Kember, G Ng, F Proceedings of the Royal Society A volume 481 issue 2328 (15 Dec 2025)
Tue, 20 Jan 2026

14:00 - 15:00
L4

Counting cycles in planar graphs

Ryan Martin
(Iowa State University)
Abstract

Basic Turán theory asks how many edges a graph can have, given certain restrictions such as not having a large clique. A more generalized Turán question asks how many copies of a fixed subgraph $H$ the graph can have, given certain restrictions. There has been a great deal of recent interest in the case where the restriction is planarity. In this talk, we will discuss some of the general results in the field, primarily the asymptotic value of ${\bf N}_{\mathcal P}(n,H)$, which denotes the maximum number of copies of $H$ in an $n$-vertex planar graph. In particular, we will focus on the case where $H$ is a cycle.

It was determined that ${\bf N}_{\mathcal P}(n,C_{2m})=(n/m)^m+o(n^m)$ for small values of $m$ by Cox and Martin and resolved for all $m$ by Lv, Győri, He, Salia, Tompkins, and Zhu.

The case of $H=C_{2m+1}$ is more difficult and it is conjectured that ${\bf N}_{\mathcal P}(n,C_{2m+1})=2m(n/m)^m+o(n^m)$. 

We will discuss recent progress on this problem, including verification of the conjecture in the case where $m=3$ and $m=4$ and a lemma which reduces the solution of this problem for any $m$ to a so-called "maximum likelihood" problem. The maximum likelihood problem is, in and of itself, an interesting question in random graph theory.

Editorial
Paseau, A Journal for the Philosophy of Mathematics volume 2 7-7 (30 Dec 2025)
Profiling vaccine attitudes and subsequent uptake in 1·1 million people in England: a nationwide cohort study
Whitaker, M Elliott, J Gerard-Ursin, I Cooke, G Donnelly, C Ward, H Elliott, P Chadeau-Hyam, M The Lancet (12 Jan 2026)
Combining the conjectures of Schanuel and Zilber-Pink
Pila, J Rendiconti Lincei. Matematica e Applicazioni
Coffee and equations
Information about the admissions test for Mathematics or joint honours.
Tue, 16 Jun 2026
15:30
L4

Wall-crossing Package via Non-Abelian Localization

Ivan Karpov
(MIT)
Abstract
Recent and seminal work of Dominic Joyce and his coauthors has produced a new (and, indeed, the first) wall-crossing machinery in the context of certain quasi-smooth moduli stacks of abelian categories: quiver representations, sheaves on Fano threefolds, and so forth.
Henry Liu has later explained how its K-theoretic version should look like.
 
Most importantly, perhaps, this machinery defines reasonable virtual fundamental classes for moduli stacks that may contain strictly semistable objects.
Unfortunately, these results do not, without further modification, apply to stacks of objects in derived categories (as opposed to abelian ones) since they require certain additional data.
This data, the so-called 'framing functor', plays an important rôle in the original constructions, and is unavailable in the derived case.
 
I shall try to explain a modest extension of Joyce-Liu’s K-theoretic Monster Wall-Crossing Formalism which, in most cases, makes it possible to dispense with this additional data, and clarifies the relation to motivic wall-crossing.
Our proof of this extension is very different from Joyce’s own, and is based instead on Halpern-Leistner’s Non-Abelian Localization (NAL) Theorem, and on the use of Blanc's topological K-theory.
 
The applications include carrying out the Feyzbakhsh–Thomas programme for Fano threefolds with even canonical class, and proving (simultaneously with R. Anderson and D. Joyce, though under stricter assumptions on the underlying variety) rationality and functional equations for generating functions of Pandharipande–Thomas invariants.
 
Time permitting, I shall also try to sketch a very short proof of the wall-crossing formula for Calabi–Yau 4-folds (conjectured by Joyce and later investigated by Bojko) which follows the NAL strategy and uses the so-called Drinfeld–Gaitsgory degeneration. This argument explains also the relation between the NAL story and the hyperbolic localization package.
 
Everything is joint with M. Moreira, and is partly in progress.
Banner for event. Abstract brain image and details.
Neural systems in general - and the human brain in particular - are organised as networks of interconnected components. Across a range of spatial scales from single cells to macroscopic areas, biological neural networks are neither perfectly ordered nor perfectly random.
Thu, 12 Mar 2026
12:45
L6

An obstruction to realizing anomalous symmetries in 1+1d lattice models

Rajath Radhakrishnan
Abstract
Realizing quantum field theories on lattice models is important for several reasons, ranging from enabling non-perturbative studies of field theories to quantum simulations. However, it is well known that not all quantum field theories can be realized on a lattice (for example, Nielsen-Ninomiya theorem).
 
In this talk, I will consider a very special aspect of this problem. Given a symmetry described by a group G with a specific choice of ’t Hooft anomaly, can it be realized in a quantum spin system, i.e., a lattice model whose Hilbert space is a tensor product of finite-dimensional Hilbert spaces associated with each site? I will describe an explicit constraint which shows that certain anomalous symmetries cannot be realized in such lattice models. 
 
Further Information

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