This term, all seminars take place Thursdays at 2pm, room MS.04 (Zeeman Building), unless indicated otherwise.

Schedule for

James Martin, 01.05.2008


05.10.2017 Yan Fyodorov (Kings College)
Exponential number of equilibria and depinning threshold for a directed polymer in a random potential.
Using the Kac-Rice approach, we show that the mean number of all possible equilibria of an elastic line (directed polymer), confined in a harmonic well and submitted to a quenched random Gaussian potential, grows exponentially ~exp(Lr) with its length L. The growth rate is found to be directly related to the generalized Lyapunov exponent of an associated Anderson localization problem of a 1d Schroedinger equation in a random potential. For strong confinement, the rate r is small and given by a non-perturbative (instanton) contribution to the Lyapunov exponent. For weak confinement, the rate r is found to be proportional to the inverse Larkin length of the pinning theory. As an application, identifying the depinning with a landscape ”topology trivialization” phenomenon, we obtain an upper bound for the depinning threshold f_c, in presence of an applied force. The presentation is based on the joint work arXiv:1703.10066 with P.Le Doussal, A. Rosso and C. Texier.
Contact: Nikos
12.10.2017 Alexandre Stauffer (University of Bath)
Activated Random Walks
We consider the activated random walk model on general vertex-transitive graphs. A central question is whether the critical density mu_c for sustained activity is strictly between 0 and 1. It was known that mu_c>0 on Z^d, dgeq 1, and that mu_c<1 on Z for small enough sleeping rate. We show that mu_c o 0 as lambda o 0 in all transient graphs, implying that mu_c<1 for small enough sleeping rate. We also show that mu_c<1 for any sleeping rate in any graph in which simple random walk has positive speed. Furthermore, we prove that mu_c>0 in any amenable graph, and that mu_cin(0,1) for any sleeping rate on regular trees. Based on a joint work with Lorenzo Taggi.
Contact: Daniel
19.10.2017 Vladislav Vysotskiy (University of Sussex)
Convex hulls of random walks
Consider the probability that the convex hull of an n-step random walk in R^d does not absorb the origin, which in dimension one means that the trajectory of the walk does not change its sign. The remarkable formula of Sparre Andersen (1949) states that any one-dimensional random walk with symmetric continuous distribution of increments stays positive with the probability (2n-1)!!/(2n)!!, which does not depend on the distribution. We prove a multidimensional distribution-free counterpart of this result and give an explicit tractable formula for the absorption probability. Our idea is to show that the absorption problem is equivalent to a geometric problem on counting the number of Weyl chambers in R^n intersected by a generic linear subspace of codimension d. This method also yields absorption probabilities for convex hulls of random walk bridges and even joint convex hulls of several symmetric random walks and random bridges. As the main application of these results, we obtain explicit distribution-free formulas for the expected number of k-dimensional faces (e.g., vertices for k=0 and hyperfaces for k = d-1) in convex hulls of random walks. This is a joint work with Zakhar Kabluchko (Munster) and Dmitry Zaporozhets (St. Petersburg).
Contact: Daniel
26.10.2017 Costanza Benassi (University of Warwick)
Random loop models: conjectures and results
Random loop models appear in a great variety of situations in both the probability and mathematical physics literature. Recently some striking conjectures have been proposed about the appearance of extended loops and the distribution of their lengths, which is expected to be a member of the Poisson Dirichlet distribution family. We propose a general class of models for interacting loops on a lattice, and we investigate how to validate these conjecture exploiting their relationship with a generalised random current model.
02.11.2017 Nils Berglund (Université d Orléans)
Metastability in stochastic Allen–Cahn PDEs
Stochastic processes subject to weak noise often show a metastable behaviour, meaning that they converge to equilibrium extremely slowly; typically, the convergence time is exponentially large in the inverse of the variance of the noise (Arrhenius law).
In the case of finite-dimensional Ito stochastic differential equations, the large-deviation theory developed in the 1970s by Freidlin and Wentzell allows to prove such Arrhenius laws and compute their exponent. Sharper asymptotics for relaxation times, including the prefactor of the exponential term (Eyring–Kramers laws) are known, for instance, if the stochastic differential equation involves a gradient drift term and homogeneous noise. One approach that has been very successful in proving Eyring–Kramers laws, developed by Bovier, Eckhoff, Gayrard and Klein around 2005, relies on potential theory.
I will describe Eyring–Kramers laws for some parabolic stochastic PDEs such as the Allen–Cahn equation on the torus. In dimension 1, an Arrhenius law was obtained in the 1980s by Faris and Jona-Lasinio, using a large-deviation principle. The potential-theoretic approach allows us to compute the prefactor, which turns out to involve a Fredholm determinant. In dimensions 2 and 3, the equation needs to be renormalized, which turns the Fredholm determinant into a Carleman–Fredholm determinant.
Based on joint work with Barbara Gentz (Bielefeld), and with Giacomo Di Gesù (Vienna) and Hendrik Weber (Warwick).

Contact: Hendrik
09.11.2017 Sergio Yuhjtman (University of Buenos Aires)

Contact: Daniel
16.11.2017 Adam Bowditch (University of Warwick)

23.11.2017 Anna Maltsev (Queen Mary University)
What the Ising model can tell us about intracellular calcium signals
Intracellular calcium signals represent a universal mechanism of cell function. Messages carried by calcium are local, rapid, and powerful enough to be delivered over the thermal noise. A higher signal to noise ratio is achieved by a cooperative action of calcium release channels arranged in clusters containing a few to several hundred release channels. The channels synchronize their openings via Ca-induced-Ca-release, generating high-amplitude local calcium signals. Despite positive feedback nature of the activation, calcium signals are strictly confined in time and space by an unexplained termination mechanism. We construct an isomorphism between such molecular clusters and an Ising model and demonstrate that the collective transition of release channels from an open to a closed state is identical to the phase transition associated with the reversal of magnetic field. This is joint work with Prof. Stern laboratory at the National Institutes of Health.
Contact: Daniel
30.11.2017 Enrico Scalas (University of Sussex)

Contact: Daniel