go to top scroll for more

Projects


Projects: Custom Search
Reference Number EP/W026775/1
Title Particles At eXascale on High Performance Computers (PAX-HPC)
Status Started
Energy Categories Renewable Energy Sources (Solar Energy, Photovoltaics) 2%;
Not Energy Related 96%;
Other Power and Storage Technologies (Energy storage) 2%;
Research Types Basic and strategic applied research 100%
Science and Technology Fields PHYSICAL SCIENCES AND MATHEMATICS (Physics) 50%;
PHYSICAL SCIENCES AND MATHEMATICS (Computer Science and Informatics) 50%;
UKERC Cross Cutting Characterisation Not Cross-cutting 100%
Principal Investigator Dr SM Woodley
No email address given
Chemistry
University College London
Award Type Standard
Funding Source EPSRC
Start Date 01 December 2021
End Date 30 November 2024
Duration 36 months
Total Grant Value £3,041,191
Industrial Sectors Chemicals
Region London
Programme SPF EXCALIBUR Programme
 
Investigators Principal Investigator Dr SM Woodley , Chemistry, University College London (99.980%)
  Other Investigator Professor SR Bishop , Mathematics, University College London (0.001%)
Professor RG Bower , Physics, Durham University (0.001%)
Dr I Bush , UNLISTED, STFC (Science & Technology Facilities Council) (0.001%)
Dr S Chulkov , School of Maths and Physic, University of Lincoln (0.001%)
Professor PV Coveney , Chemistry, University College London (0.001%)
Dr T De Vuyst , School of Engineering and Technolog, University of Hertfordshire (0.001%)
Dr N Drummond , Physics, Lancaster University (0.001%)
Dr A Elena , Scientific Computing Department, STFC (Science & Technology Facilities Council) (0.001%)
Dr G Fourtakas , Mechanical, Aerospace and Civil Engineering, University of Manchester (0.001%)
Dr PJ Hasnip , Physics, University of York (0.001%)
Professor L Kantorovich , Physics, King's College London (0.001%)
Dr ST Kay , Physics and Astronomy, University of Manchester (0.001%)
Dr TW Keal , Scientific Computing Department, STFC (Science & Technology Facilities Council) (0.001%)
Dr O Kenway , Information Services Division, University College London (0.001%)
Dr SM Longshaw , Scientific Computing Department, STFC (Science & Technology Facilities Council) (0.001%)
Dr BD Rogers , Mechanical, Aerospace and Civil Engineering, University of Manchester (0.001%)
Dr C Skylaris , School of Chemistry, University of Southampton (0.001%)
Dr LA Smith , Edinburgh Parallel Computing Centre, University of Edinburgh (0.001%)
Dr MB Watkins , School of Maths and Physic, University of Lincoln (0.001%)
Professor T Weinzierl , Computer Scienc, Durham University (0.001%)
  Industrial Collaborator Project Contact , National Renewable Energy Laboratory (NREL), USA (0.000%)
Project Contact , University of Manchester (0.000%)
Project Contact , Durham University (0.000%)
Project Contact , ETH Zurich, Switzerland (0.000%)
Project Contact , Numerical Algorithms Group Ltd (0.000%)
Project Contact , NVIDIA Corporation, USA (0.000%)
Project Contact , Leiden University, The Netherlands (0.000%)
Project Contact , DiRAC (Distributed Res utiliz Adv Comp) (0.000%)
Project Contact , Duke University (0.000%)
Web Site
Objectives
Abstract Many recent breakthroughs would not have been possible without access to the most advanced supercomputers. For example, for the Chemistry Nobel Prize winners in 2013, supercomputers were used to develop powerful computing programs and software, to understand and predict complex chemical processes or for the Physics Nobel Prize in 2017 supercomputers helped to make complex calculations to detect hitherto theoretical gravitational waves.The advent of exascale systems is the next dramatic step in this evolution. Exascale supercomputing will enable new scientific endeavour in wide areas of UK science, including advanced materials modelling, engineering and astrophysics. For instance, solving atomic and electronic structures with increasing realism to solve major societal challenges - quantum mechanically detailed simulation and steering design of batteries, electrolytic cells, solar cells, computers, lighting, and healthcare solutions, as well as enabling end-to-end simulation of transients (such as bird strike) in a jet engine, to simulation of tsunami waves over-running a series of defensive walls, or understanding the universe at a cosmological scale. Providing a level of detail to describe accurately these challenging problems can be achieved using particle-based models that interact in complicated dance that can be visualised or analysed to see how our model of nature would react in various situations. To model problems as complex as outlined the ways the particles interact must be flexible and tailored to the problem and vast quantities of particles are needed (and or complicated interactions). This proposal takes on the challenge of efficiently calculating the interacting particles on vast numbers of computer cores. The density of particles can be massively different at different locations, and it is imperative to find a way for the compute engines to have similar amounts of work - novel algorithms to distribute the work over different types of compute engines will be developed and used to develop and run frontier simulations of real-world challenges. There is a high cost of both purchasing and running an exascale system, so it is imperative that appropriate software is developed before users gain access to exascale facilities. By definition, exascale supercomputers will be three orders of magnitude more powerful than current UK facilities, which will be achieved by a larger number of cores and the use of accelerators (based on gaming graphic cards, for example). This transition in computer power represents both an anticipated increase in hardware complexity and heterogeneity, and an increase in the volume of communication between cores that will hamper algorithms used on UK's current supercomputers. Many, if not all, of our software packages will require major changes before the hardware architectures can be fully exploited. The investigators of this project are internationally leading experts in developing (enabling new science) and optimising (making simulations more efficient) state-of-the-art particle-based software for running simulations on supercomputers, based here and abroad. Software that we have developed is used both in academia and in industry. In our project we will develop solutions and implement these in our software and, importantly, train Research Software Engineers to become internationally leading in the art of exploiting exascale supercomputers for scientific research
Publications (none)
Final Report (none)
Added to Database 15/12/21