D is for Diophantine Equations by Dr Jonathan Pila FRS.
Fri, 17 Jun 2016
14:00 -
15:00
L3
Development of patient-specific multi-scale models to understand atherogenesis: comparison with in vivo data
Dr Vanessa Diaz
(Dept of Department of Mechanical Engineering University College London)
Fri, 10 Jun 2016
14:00 -
15:00
L3
Does cell surface heterogeneity affect adhesion?
Professor Brian Wood
(School of Chemical Biological & Environmental Engineering Oregon State University)
Fri, 03 Jun 2016
14:00 -
15:00
L3
The impact of geometry and diffusion barriers in cell polarity and receptor dynamics
Dr Tatiana Márquez-Lago
(Integrative Systems Biology Unit Okinawa Institute of Science and Technology)
Fri, 27 May 2016
14:00 -
15:00
L3
From 'omics data to landscapes: dimensionality reduction and clustering through geometric graphs
Professor Mauricio Barahona
(Dept of Mathematics Imperial College London)
Fri, 20 May 2016
14:00 -
15:00
L3
Alignment-free sequence and network comparison
Professor Gesine Reinert
(Dept of Statistics University of Oxford)
Fri, 13 May 2016
14:00 -
15:00
L3
Bayesian parameter estimation for stochastic dynamic biological models
Professor Darren Wilkinson
(School of Mathematics & Statistics Newcastle University)
Fri, 06 May 2016
14:00 -
15:00
L3
Can puzzles self-assemble?
Professor Daan Frenkel
(Dept of Chemistry University of Cambridge)
Abstract
A holy grail of nano-technology is to create truly complex, multi-component structures by self assembly.
Most self-assembly has focused on the creation of `structural complexity'. In my talk, I will discuss `Addressable Complexity': the creation of structures that contain hundreds or thousands of
distinct building blocks that all have to find their place in a 3D structure.
Fri, 29 Apr 2016
14:00 -
15:00
L1
Gene regulatory systems under epigenetic regulation: robustness, noise-enabled bifurcations, and cellular reprogramming
Dr Tomas Alarcon
(Centre de Recerca Matematica)
The Norwegian Academy of Science and Letters has decided to award the Abel Prize for 2016 to Sir Andrew J. Wiles (62), University of Oxford, “for his stunning proof of Fermat’s Last Theorem by way of the modularity conjecture for semistable elliptic curves, opening a new era in number theory.”