A consortium of teams from 6 universities aims to achieve major advances in a technology that potentially produces electricity directly from sustainable biological materials and air, in devices known as biological fuel cells. These devices are of two main types: in microbial fuel cells micro-organisms convert organic materials into fuels that can be oxidised in electrochemical cells, and in enzymatic fuel cells electricity is produced as a result of the action of an enzyme (a biological catalyst). Fuels that can be used include (1) pure biochemicals such as glucose, (2) hydrogen gas and (3) organic chemicals present in waste water.The Consortium programme involves a unique combination of microbiology, enzymology, electrochemistry, materials science and computational modelling. Key challenges that the Consortium will face include modelling and understanding the interaction of an electrochemical cell and a population of micro-organisms, attaching and optimising appropriate enzymes, developing and studying synthetic assemblies that contain the active site of a natural enzyme, optimising electrode materials for this application, and designing, building and testing novel biological fuel cells.A Biofuel Cells Industrial Club is to be formed, with industrial partners active in water management, porous materials, microbiology, biological catalysis and fuel cell technology. The programme and its outcomes will be significant steps towards producing electricity from materials and techniques originating in the life sciences. The technology is likely to be perceived as greener than use of solely chemical and engineering approaches, and there is considerable potential for spin off in changed technologies (e.g. cost reductions, reduction in the need for precious metals, biological catalysts for production of hydrogen by electrolysis).

The water industry is the fourth most energy intensive secotr in the UK and uses approximately 2 -3 % of net UK electricity releasing approximately four million tonnes of green house gas emissions (carbon dioxide equivalent) every year. The industry is making progress to produce more renewable energy from its waste biomass sources. However, only 493 GWh was generated by water utilities in the UK in 2005/06 about 6.4 % of its actual requirements. The government has called for research into potentially more efficient energy generation technologies from biomass which would contribute significantly to the UK's policy objectives of 10% of electricity supply from renewable energy by 2010 and for the reduction of greenhouse gas emissions. Innovative research into low carbon treatment and production and storage and use of biogas in the water sector has the potential to offer step-change benefits to the UK's energy system. This project seeks to secure a paradigm shift in wastewater treatment and biogas application. A pilot scale feasibility study is proposed to examine: (1) the fundamental operation of an anaerobic bioreactor using fortified influent wastewater; and (2) increasing the energy-production capacity of the generated renewable biogas. This approach significantly alters the wastewater treatment flow-sheet by reducing dependence on the energy intensive activated sludge process. The project has the potential for UK energy savings of 0.12 kWh per cubic metre of wastewater treated. Over 1 million cubic metres of wastewater are treated every day which potentially corresponds to savings of 438GWh per year and 188,469 tonnes of carbon dioxide per year. This is approximately equivalent to off setting 122,000 people flying London to New York return. Potentially fortified anaerobic treatment will also yield >10 % more biogas than is currently available from anaerobic digesters. Therefore, it is important to increase its energy production capacity in line with government developments for local energy and increased energy security. Currently biogas is used in combined heat and power in the UK water sector but biogas use in fuel cells, as a transport gas and for gas supply could provide greater flexibility and efficiency with more storage opportunities. However, these applications require biogas to be upgraded. This project seeks to examine in-situ methane enrichment to provide a better economy of scale for upgrading biogas and thereby maximising the overall energy production capacity of wastewater carbon. This project will therefore help to provide the 'scientific advance and industrial innovation to utilise biomass to meet the increasing demands for sustainable products from renewable sources' called for by the government.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

Reliable water supply is fundamental to human health and wellbeing, and in the UK is underpinned by inter-linked infrastructure for abstraction, storage, treatment and conveyance of potable and wastewater. Climate change has the potential to affect the UK water system in a number of ways: through changes in the water available for abstraction and storage, especially through altered drought frequency and intensity, changes in demand and changing risk of infrastructure failure.This project aims to develop a set of analysis tools and data on climate change and future demand that will enable users to identify packages of options that results in heightened reslience of the UK water system to these uncertain future drivers. The multi-criteria approach to be developed will also allow alternative adaptation options to be assessed against other criteria, such as environmental sustatinability, energy costs and public acceptability.The focus of the study is South and East England, an area that is already experiencing water system stress, and likely to be subject to additional stresses in the future due to climate change and demographic changes.The methods and results of this research will enable the UK to better plan for adaptation of the water system to climate change, and will help identify the polciy and regulatory changes that would be needed for adaptation to take place.The project has been designed in collaboration with stakeholders from government (DEFRA, EA, OFWAT, GLA), the water industry (UKWIR, Water UK and a number of water companies) and NGOs with an interest in water. These same stakeholders will be involved throughout the project as project partners.