

Fractal Geometry and Dimension Theory
Roughly speaking, ‘fractals’ are sets which exhibit interesting structures at arbitrarily small scales. Such
objects appear naturally across science and studying them in a rigorous mathematical framework is of
great interest. Falconer’s textbook: Fractal Geometry: Mathematical Foundations and Applications is a
standard reference in the field and is used for teaching and research across the world. Many fractals,
including selfsimilar and selfaffine sets, are often modelled as attractors of iterated function systems. We
are interested in various properties of these sets, including the relationship between their geometry and
their dimension theory. Falconer pioneered the study of the Hausdorff dimension of selfaffine sets in the
1980s, but this topic is still very much in vogue today. Indeed, Falconer and Kempton have recently been
involved in linking the problem to dynamically defined measures on an associated projective space. Fraser
has investigated Assouad dimension in a variety of contexts, including showing that there is no direct
analogue of Marstrand’s Projection Theorem for Assouad dimension.

Dynamical Systems and Ergodic Theory
Dynamical systems is the study of systems which evolve in time (discrete or continuous) with a view to
understanding the longterm behaviour. However, these systems often exhibit `chaotic’ signatures,
rendering a complete understanding impossible. Ergodic theory can be applied to these problems, taking a
probabilistic viewpoint to investigate the average statistical behaviour of the system. The fundamental
objects here are measures: which ones are important, and, what happens for typical points for these
measures under the dynamics. The speed at which the system begins to look `completely random’ is a key
signature of the chaotic behaviour. Thermodynamic formalism provides a toolbox for investigating
interesting measures, speeds of mixing, and probabilistic laws. Todd uses these ideas to understand
systems which mix very slowly (the `least chaotic’ systems), or do not quite mix at all (transient systems).
These are particularly interesting because the intermittency (predictable phases interspersed with chaotic
bursts) these systems exhibit is seen in numerous realworld applications. Todd’s main interest is in
understanding the statistical behaviour of elementary models, in order to investigate what should be the
signatures of the abovementioned more sophisticated models.

Multifractal Geometry
The measuretheoretic multifractal formalism introduced in the 1990s by Olsen is now standard in rigourous
multifractal analysis and has been used in many questions involving analysis of measures. Topics we study
from a multifractal viewpoint include: selfaffine measures, statistically selfsimilar measures, divergence
points, points of nondifferentiability of functions, and inhomogeneous measures. More recently, Olsen has
used zeta functions to analyse the multifractal properties of selfsimilar and selfconformal measures,
bringing together ideas from dynamical systems, complex analysis and geometric measure theory.

Stochastic Processes
Stochastic processes, including Gaussian and stable processes, are used increasingly to model highly
irregular phenomena. Our recent work on fractal stochastic processes has concerned the localisibility of
such processes, that is, their local form when scaled about particular points. In collaboration with French
mathematicians Falconer has constructed 'multistable processes', where the stability index varies with time,
and ‘selfregulating processes’ where the stability index depends on the value of the process at any instant.
Related work has involved studying the Fourier transform of measures supported on graphs of random
functions, such as Brownian and fractional Brownian motion. Fraser and his collaborators proved that such
graphs are almost surely not Salem, i.e. the Hausdorff dimension is not witnessed by Fourier decay.

Group Actions, Dynamics, and Group Theory
Automorphisms of one and twosided shift spaces, and the R. Thompson family of groups are central
examples of groups of homeomorphisms of spaces, which have a long pedigree of relevance to many
disparate fields of mathematics research. Bleak and his collaborators have analysed these groups through
studying properties of their actions on relevant Cantor spaces. Techniques used in this study come from
many areas including: algebra, theoretical computer science, combinatorics, symbolic dynamics, and
analysis.
