Crossing Boundaries in Energy Storage
Reference Number
EP/I022570/1
Title
Crossing Boundaries in Energy Storage
Status
Completed
Energy Categories
Other Power and Storage Technologies(Energy storage)
Hydrogen and Fuel Cells(Hydrogen, Hydrogen storage)
Hydrogen and Fuel Cells(Hydrogen, Hydrogen storage)
Research Types
Basic and strategic applied research
Science and Technology Fields
PHYSICAL SCIENCES AND MATHEMATICS (Chemistry)
ENGINEERING AND TECHNOLOGY (Chemical Engineering)
ENGINEERING AND TECHNOLOGY (Chemical Engineering)
UKERC Cross Cutting Characterisation
Not Cross-cutting
Principal Investigator
Professor P Bruce
Chemistry
University of St Andrews
Chemistry
University of St Andrews
Award Type
Standard
Funding Source
EPSRC
Start Date
01 August 2011
End Date
31 December 2013
Duration
29 months
Total Grant Value
£3,039,217
Industrial Sectors
Energy
Region
Scotland
Programme
Energy : Energy
Other Investigator
Dr PA Connor, Chemistry, University of St Andrews
Professor D Gregory, Chemistry, University of Glasgow
Professor PJ Hall, Chemical and Biological Engineering, University of Sheffield
Professor J Irvine, Chemistry, University of St Andrews
Professor K Scott, School of Chemical Engineering & Advanced Materials, Newcastle University
Professor D Gregory, Chemistry, University of Glasgow
Professor PJ Hall, Chemical and Biological Engineering, University of Sheffield
Professor J Irvine, Chemistry, University of St Andrews
Professor K Scott, School of Chemical Engineering & Advanced Materials, Newcastle University
Web Site
Objectives
Abstract
Energy storage is more important today than at any other time in history. Approx. 25% of CO2 emissions arise from burning fossil fuels in transportation. It is widely acknowledged that decarbonising transport is imperative and involves electrification.The greatest challenge facing electrification of transport is energy storage. Although electric and plug-in hybrid electric vehicles (EVs) will be with us in increasing numbers over the next decade, achieving a step change in driving range (e.g. the often stated Holy Grail of +300 miles) is impossible with the storage technologies available now and in the near term (lithium-ion batteries). Here we propose to investigate energy storage technologies far beyond the current horizon and with the potential to deliver a step change in performance of electric vehicles. We focus in particular on the Li-air battery, hydrogen and oxygen storage, in line with the scope of the call. These technologies fit into an overall vision for future hybrid EVs in which the Li-air battery, the hydrogen fuel cell (or perhaps ammonia fuel cell) and the reversible fuel cell (effectively a hydrogen-oxygen battery) play key roles.The Li-air battery has the potential to store far more energy than current generation lithium batteries but major hurdles remain to be overcome. Here we address some of the key hurdles facing a step change of Li-air batteries, opening the way to practical Li-air batteries in the longer term capable of a much extended driving range and available at lower cost than today and hence transforming transportation.Similarly we address the key challenge of hydrogen storage by a concerted series of approaches to identify the solid state stores that meet the criteria for a transformation in the mobile storage of hydrogen for transport.We also examine the radical concept of solid state oxygen storage using transition metal and peroxo compounds. Such stores would find applications as sources and sinks of O for the cathode in a Li-air cell or for a reversible fuel cell.By working together we break down the traditional boundaries between these research fields, enable the cross-fertilisation of ideas that may lead to innovative solutions to the problems of each field and train personnel in a culture of working across these boundaries
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Added to Database
22/09/11
