Join us in the Radcliffe Science Library to plant a plug (young plant) in a pot, pack in compost and take away the plant with you. Book your place and enjoy the texture of fresh soil on your hands and the joy of a plant to bring home. Drop in anytime during the 2 hour slot.
Date: Wednesday 12 June
Time: 10am-12pm
Location: Wellbeing Room, Radcliffe Science Library
The University of Glasgow is offering a unique opportunity for a Research Associate to make a leading contribution to the Centre for Future Percutaneous Coronary Intervention Planning. The vision of the Centre is to develop novel and robust mathematical and statistical methodologies, supported by large clinical data sets, to create computational tools for optimisation of cardiovascular procedures.
Professor of Earth and Planetary Fluid Dynamics
Centre for Environmental and Industrial Flows
Department of Earth Sciences
Department of Applied Mathematics and Theoretical Physics
University of Cambridge
Research interests: The research in the Earth and Planetary Fluid Dynamics group focuses on using mathematical models and laboratory experiments to understand the fluid behaviour of the Earth and other planetary bodies. Current research interests include the consequences of subglacial hydrology on supraglacial lake drainage and the tidal modulation of ice streams, the solidification of magma oceans and the early generation of magnetic fields on planetary bodies, the erosive dynamics of idealised river systems, the emplacement and solidification of magmatic flows, viscous tectonic mountain building, and the general fluid dynamics of geological carbon storage.
The response of the Greenland and Antarctic ice sheets to a changing climate is one of the largest sources of uncertainty in future sea level predictions. The behaviour of the subglacial environment, where ice meets hard rock or soft sediment, is a key determinant in the flux of ice towards the ocean, and hence the loss of ice over time. Predicting how ice sheets respond on a range of timescales brings together mathematical models of the elastic and viscous response of the ice, subglacial sediment and water and is a rich playground where the simplified models of the contact between ice, rock and ocean can shed light on very large scale questions. In this talk we’ll see how these simplified models can make sense of a variety of field and laboratory data in order to understand the dynamical phenomena controlling the transient response of large ice sheets.