Plasma Physics HEC Consortia

Completed

Nuclear Fission and Fusion(Nuclear Fusion)
Not Energy Related

Basic and strategic applied research

PHYSICAL SCIENCES AND MATHEMATICS (Physics)
PHYSICAL SCIENCES AND MATHEMATICS (Computer Science and Informatics)

Not Cross-cutting

Prof TD Arber
Physics
University of Warwick

Standard

EPSRC

29 May 2013

28 May 2018

60 months

£279,240

Plasma physics

West Midlands

NC : Infrastructure

Prof TD Arber, Physics, University of Warwick

Dr M Ashworth, CSE/Advanced Research Computing (COO), STFC (Science & Technology Facilities Council)
Professor AR Bell, Oxford Physics, University of Oxford
Professor J Chittenden, Department of Physics (the Blackett Laboratory), Imperial College London
Dr BD Dudson, Physics, University of York
Professor RG Evans, Department of Physics (the Blackett Laboratory), Imperial College London
Dr P McKenna, Physics, University of Strathclyde
Dr BF McMillan, Physics, University of Warwick
Professor PA Norreys, Oxford Physics, University of Oxford
Dr CP Ridgers, Physics, University of York
Dr CM Roach, Culham Centre for Fusion Energy, EURATOM/CCFE
Professor H Wilson, Physics, University of York

Plasma physics is the study of the properties of fully ionised gases or dense matter that exhibits similar collective behaviour. The processes, which need to be investigated, therefore cover kinetic theory of matter far from its equilibrium state, fluid dynamics of magnetised and conductive plasmas and the interaction of these processes across a huge range of time and length scales, often in complex geometries. Such problems are rarely tractable analytically and thus much of plasma physics resorts to High End Computing (HEC) to perform massive simulations.This planned HEC Consortium will cover all aspects of computational plasma physics. This includes modelling for magnetic confinement fusion (MCF) devices to optimize reactor performance, simulations to optimize laser-particle accelerator sources, novel approaches to high-intensity laser plasma experiments and laser-driven fusion. In all these areas High End Computing (HEC) resources are needed for simulations which are essential to either guiding experiments and research programmes (including a reliable predictive capability for the performance of future plasma facilities) or interpreting the complex diagnostic sets from coupled multi-scale, non-linear and often relativistic processes.To help maintain the UK's leading role in fusion reactor design and basic plasma physics the HEC Consortium requires a block allocation of UK National level computing resource. This will ease the access to such facilities and allow the UK to collectively plan computational programmes, which will require many years to complete, in the certainty that the computing resources will be available. Over the five-year duration of this HEC Consortium grant HEC architectures are likely to change and optimising codes for current and future machines is therefore essential. In addition new physics packages must be developed and implemented to keep the UK at the cutting edge of this research. The Consortium therefore also requires funding for software development to exploit the computing resources and keep codes world-leading.The proposed HEC Consortium will therefore conduct simulations in support of the UK fusion programme; software development for novel physical processes and maintain the scientific impact of plasma and laser physics

16/08/13