Prof. Eamonn Gaffney

Status

Academic Faculty

Professor of Applied Mathematics

Tutorial Fellow, Senior Mathematics Tutor, Tutor for Graduates, Brasenose College

Contact form

http://people.maths.ox.ac.uk/gaffney/

+44 1865 283876

ORCID iD

https://orcid.org/0000-0002-6888-4362

Research groups

Mathematical Biology

Address
Mathematical Institute
University of Oxford
Andrew Wiles Building
Radcliffe Observatory Quarter
Woodstock Road
Oxford
OX2 6GG

Recent publications

A mathematical model of aqueous humor production and composition

Dvoriashyna, M Foss, A Gaffney, E Repetto, R Investigative Ophthalmology and Visual Science volume 63 issue 9 (02 Aug 2022)

A method for the inference of cytokine interaction networks

Coles, M Jansen, J Uhlig, H Aschenbrenner, D Gaffney, E PLoS Computational Biology volume 18 issue 6 (22 Jun 2022)

The control of particles in the Stokes limit

Walker, B ishimoto, K Gaffney, E moreau, C Journal of Fluid Mechanics volume 942 (13 May 2022)

Canonical orbits for rapidly deforming planar microswimmers in shear ﬂow

Gaffney, E Dalwadi, M moreau, C ishimoto, K Walker, B Physical Review Fluids volume 7 (18 Feb 2022)

Effects of rapid yawing on simple swimmer models and planar Jeffery's orbits

Walker, B Ishimoto, K Gaffney, E Moreau, C Dalwadi, M Physical Review Fluids volume 7 issue 2 (04 Feb 2022)

Introduction to 'Recent progress and open frontiers in Turing's theory of morphogenesis'.

Krause, A Gaffney, E Maini, P Klika, V Philosophical transactions. Series A, Mathematical, physical, and engineering sciences volume 379 issue 2213 20200280- (Dec 2021)

Modern perspectives on near-equilibrium analysis of Turing systems.

Krause, A Gaffney, E Maini, P Klika, V Philosophical transactions. Series A, Mathematical, physical, and engineering sciences volume 379 issue 2213 20200268- (01 Dec 2021)

Research interests

My research objectives are typically to extract the macroscale consequences of mechanisms operating at much smaller scales, usually the microbiological level, for instance how cells interact and signal, together with the associated biophysics of reaction, diffusion, deformation and flow. This requires detailed mathematical modelling, combined with mathematical analyses, asymptotics, computation and model interpretation within numerous application areas of the life and biomedical sciences. The application areas include cell motility, especially flagellated cell swimming, bacterial dynamics, ecological invasions and mechanisms of biological self-organisation together with the modelling of select processes in physiological transport and solid tumour development.