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Projects

Projects: Projects for Investigator
Reference Number EP/K016288/1
Title Energy Materials: Computational Solutions
Status Completed
Energy Categories Renewable Energy Sources(Solar Energy, Photovoltaics) 25%;
Other Power and Storage Technologies(Electric power conversion) 25%;
Other Power and Storage Technologies(Energy storage) 25%;
Hydrogen and Fuel Cells(Fuel Cells) 25%;
Research Types Basic and strategic applied research 100%
Science and Technology Fields PHYSICAL SCIENCES AND MATHEMATICS (Chemistry) 100%
UKERC Cross Cutting Characterisation Not Cross-cutting 100%
Principal Investigator Professor S Islam

Materials
University of Oxford
Award Type Standard
Funding Source EPSRC
Start Date 20 May 2013
End Date 19 May 2019
Duration 72 months
Total Grant Value £3,270,295
Industrial Sectors Energy
Region South East
Programme Energy : Physical Sciences, NC : Physical Sciences
 
Investigators Principal Investigator Professor S Islam , Materials, University of Oxford (99.995%)
  Other Investigator Professor SC Parker , Chemistry, University of Bath (0.001%)
Dr A (Aron ) Walsh , Chemistry, University of Bath (0.001%)
Dr NH De Leeuw , Chemistry, University College London (0.001%)
Professor R Catlow , Chemistry, University College London (0.001%)
Dr P Sherwood , CSE/Computational Chemistry Group, STFC (Science & Technology Facilities Council) (0.001%)
  Industrial Collaborator Project Contact , Johnson Matthey plc (0.000%)
Project Contact , Sharp Laboratories of Europe Ltd (0.000%)
Web Site
Objectives
Abstract The provision of clean sustainable energy is among the most urgent challenges to society and to the global economy, and poses fundamental, exciting scientific questions. Materials performance lies at the heart of the development and optimisation of green energy technologies, and computational methods now play a vital role in modelling and predicting the structures, properties and reactivity of complex materials. UK science has an enviable position in the international field, and many key techniques and applications were pioneered here.Particular strengths of the UK community have been the ability to harness the full range of techniques from force-field to electronic structure methods, the effective exploitation of high performance computing facilities, the extensive range of applications and the synergistic relationship with experiment. All these aspects will feed into our collaborative project and, indeed, our team has leading programmes involving both technique development and applications, which exploit the latest development in computational hardware and software.The performance of energy storage and conversion devices is controlled by the atomistic and electronic processes within bulk materials, nano-structures, and across interfacial boundaries. These processes remain, however, poorly understood. The vision of this project is therefore to develop and apply predictive techniques for modelling the atomic level operation of energy materials, thereby enabling both academic and industrial communities to develop new materials for the next generations of energy devices with a step change in performance; and thereby addressing specifically the following critical technological objectives, which will push the RCUK energy agenda forward: (i) increasing the efficiency and stability of solar cells; (ii) enhancing the energy density and charge rate of lithium-ion batteries; (iii) improving the performance and lifetime of solid oxide fuel cells, and (iv) increasing the power from thermoelectric devices.To address these ambitious and exciting challenges, we require a concerted and systematic programme combining a range of state-of-the-art simulation methods with new techniques to work on the following major Themes: (a) exploration of materials; (b) nanostructures and interfaces; (c) ionic and electronic transport; and (d) new technique development. Hence, we have brought together a consortium team from the University of Bath, UCL and Daresbury, with wide and complementary experience in the field. There is no equivalent concerted programme inter-linking different expertise being undertaken elsewhere, and hence will be world-leading in this domain. Indeed, the project will ensure that the UK community remains ahead of the international competition in the fieldThe provision of clean sustainable energy is among the most urgent challenges to society and to the global economy, and poses fundamental, exciting scientific questions. Materials performance lies at the heart of the development and optimisation of green energy technologies, and computational methods now play a vital role in modelling and predicting the structures, properties and reactivity of complex materials. UK science has an enviable position in the international field, and many key techniques and applications were pioneered here.Particular strengths of the UK community have been the ability to harness the full range of techniques from force-field to electronic structure methods, the effective exploitation of high performance computing facilities, the extensive range of applications and the synergistic relationship with experiment. All these aspects will feed into our collaborative project and, indeed, our team has leading programmes involving both technique development and applications, which exploit the latest development in computational hardware and software.The performance of energy storage and conversion devices is controlled by the atomistic and electronic processes within bulk materials, nano-structures, and across interfacial boundaries. These processes remain, however, poorly understood. The vision of this project is therefore to develop and apply predictive techniques for modelling the atomic level operation of energy materials, thereby enabling both academic and industrial communities to develop new materials for the next generations of energy devices with a step change in performance; and thereby addressing specifically the following critical technological objectives, which will push the RCUK energy agenda forward: (i) increasing the efficiency and stability of solar cells; (ii) enhancing the energy density and charge rate of lithium-ion batteries; (iii) improving the performance and lifetime of solid oxide fuel cells, and (iv) increasing the power from thermoelectric devices.To address these ambitious and exciting challenges, we require a concerted and systematic programme combining a range of state-of-the-art simulation methods with new techniques to work on the following major Themes: (a) exploration of materials; (b) nanostructures and interfaces; (c) ionic and electronic transport; and (d) new technique development. Hence, we have brought together a consortium team from the University of Bath, UCL and Daresbury, with wide and complementary experience in the field. There is no equivalent concerted programme inter-linking different expertise being undertaken elsewhere, and hence will be world-leading in this domain. Indeed, the project will ensure that the UK community remains ahead of the international competition in the fieldThe provision of clean sustainable energy is among the most urgent challenges to society and to the global economy, and poses fundamental, exciting scientific questions. Materials performance lies at the heart of the development and optimisation of green energy technologies, and computational methods now play a vital role in modelling and predicting the structures, properties and reactivity of complex materials. UK science has an enviable position in the international field, and many key techniques and applications were pioneered here.Particular strengths of the UK community have been the ability to harness the full range of techniques from force-field to electronic structure methods, the effective exploitation of high performance computing facilities, the extensive range of applications and the synergistic relationship with experiment. All these aspects will feed into our collaborative project and, indeed, our team has leading programmes involving both technique development and applications, which exploit the latest development in computational hardware and software.The performance of energy storage and conversion devices is controlled by the atomistic and electronic processes within bulk materials, nano-structures, and across interfacial boundaries. These processes remain, however, poorly understood. The vision of this project is therefore to develop and apply predictive techniques for modelling the atomic level operation of energy materials, thereby enabling both academic and industrial communities to develop new materials for the next generations of energy devices with a step change in performance; and thereby addressing specifically the following critical technological objectives, which will push the RCUK energy agenda forward: (i) increasing the efficiency and stability of solar cells; (ii) enhancing the energy density and charge rate of lithium-ion batteries; (iii) improving the performance and lifetime of solid oxide fuel cells, and (iv) increasing the power from thermoelectric devices.To address these ambitious and exciting challenges, we require a concerted and systematic programme combining a range of state-of-the-art simulation methods with new techniques to work on the following major Themes: (a) exploration of materials; (b) nanostructures and interfaces; (c) ionic and electronic transport; and (d) new technique development. Hence, we have brought together a consortium team from the University of Bath, UCL and Daresbury, with wide and complementary experience in the field. There is no equivalent concerted programme inter-linking different expertise being undertaken elsewhere, and hence will be world-leading in this domain. Indeed, the project will ensure that the UK community remains ahead of the international competition in the field
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Added to Database 15/08/13