• Energy Research
• UK Research and Innovation close
• 2013 close
• 2016 close

The research we propose will address the challenge of thermal energy service delivery in rural areas of developing countries, where it is projected that more than 2.6 billion people could remain without service in 2030. The research will study the existing experience in providing thermal energy for cooking, space heating and sanitation using different approaches. The research will study a particular business model called "fee-for-service" (where users pay for the energy service delivered) and different energy delivery options to provide thermal energy in rural places. The fee-for service approach relies on the delivery of a service by a private provider against a small monthly fee. The private provider makes the investment and the end-users can benefit of a service without having to pay large sum up-front. This is of particular importance in rural areas where people cannot afford to pay for a Solar Water Heater. The fee-for-service approach has been quite successfully used for the dissemination of Solar Home Systems (and also LPG) in a number of African countries. This research will build the conditions to replicate this to the sector of thermal energy services. This research will study applicable energy conversion and end-use application technologies, analyse institutional arrangements, develop business and enterprise models which needs to be implemented to promote thermal energy services in rural areas developing countries The research will analyse the respective role of government and private partners to form Public-Private-Partnership (PPP) models for energy services like thermal energy in rural areas. It will study innovative financing models that are relevant to the issue. All these components are linked and contribute to the sustainability of the model. Based on these extensive research the description of a sustainable model for thermal energy services will be developed as a generic Public-Private-Partnership model. Scholarly publications and reports will be written on the research findings to address the research gap in this area. The fee-for service thermal energy service model will be used to influence the implementation of a rural energy pilot project in Lesotho and support will be provided by the team of researchers to the government of Lesotho during implementation. Lessons will be drawn from the implementation and possibility for replication will have been explored in a second developing country -Kenya.

The UK has a world class reputation for design and manufacture of space based technologies. A new National Space Academy has been launched this year to help boost the size and quality of the UK's science and engineering expertise. The proposal supports strongly The UK Space Directory, an organisation of eight groups representing and supporting the UK space community and including the Technology Strategy Board that state "the UK Space Industry has come together to propose an ambitious 20 year strategy to capture 10% of the global space market, £40 billion, by 2030 and in doing so create 100,000 UK jobs". The UK houses some of the leading companies in space applications such as; Inmarsat, Rolls Royce, Logica, Vega Space, Astrium, Qioptiq Space Technology and Surrey Satellite Technology Limited. The latter two companies strongly back the research detailed within this proposal and have both provided satements of support. This proposal seeks to offer an alternative PV technology for large area arrays and to be the first to report thin film cadmium telluride (CdTe) deposited directly onto toughened cerium-doped microsheet glass (CMG), explicitly targeting a significant increase in specific power by a step-change reduction of system weight. The Qioptiq Space Technology CMG microsheet glass is optimised to match the coefficient of thermal expansion (CTE) of gallium arsenide (GaAs) based space solar cells. With the CdTe CTE almost identical to that of GaAs the choice of CMG is ideal for the prevention of delamination under the severe thermal gradients to which space PV is exposed. This adventurous approach, using the CMG as both the radiation barrier and substrate, will be proven by characterisation of 5 x 5 cm2 deposited devices and finally scaled to 10 x 20 cm2 on the Centre for Solar Energy Research (CSER) pilot metalorganic chemical vapour deposition (MOCVD) system. This proposal has the content and vision to make a significant contribution to the UK's flourishing space industry. Key to the success of the project will be the dissemination and pathways to impact of the research outcomes; this will be ensured through regular reporting to and feedback from a steering group of potential exploiters-Industrial experts and through targeted press releases. This proposal offers UK research the chance to impact the space PV market either through licencing of the arising IP and more excitingly in the current economic climate through manufacture of the final product.

Reports concerning dwindling reserves of fossil fuels and concerns over fuel security are frequent news headlines. The rising costs of fuel are a daily reminder of the challenges faced by a global society with ever increasing energy demands. In this context it is perhaps surprising that so many of the renewable energy supplies available to us, namely, sunlight, winds and waves, remain largely untapped resources. This is mainly due to the challenges that exist in converting these energy forms into fuels from which energy can be released 'on demand' when we wish to play computer games, drive a car and so on. However, during plant photosynthesis fuels are made naturally from the energy in sunlight. Light absorption by the green chlorophyll pigments generates an energised electron that is directed, along chains of metal centres, to catalysts that make sugars. These sugars fuel us, and all animals, when their energy is released following digestion of a meal. However, using farmed plants to produce biofuels is controversial as agriculture is also required to feed the world. As a consequence, and inspired by natural processes, we propose to build a system for artificial photosynthesis. In essence, we wish to place tiny solar-panels on microbes in order to harness sunlight to drive the production of hydrogen - a fuel from which the technologies to release energy on demand are well-advanced. We will use dyes and semi-conductor particles as mechanically and chemically robust materials to capture the energy in sunlight and generate energised electrons. We will couple these particles to biology's version of conducting wires. These wires are made from heme proteins that span membranes that provide Nature's solution to compartmentalising water-filled chambers (i.e., the inside of the bacterium). The heme-wires are produced naturally by 'rock-breathing' microorganisms and after these wires have transferred the energised electrons across the membrane they will drive enzyme catalysis to produce hydrogen Our novel bio-mimetic photocatalysts will establish new principles for the design of homogeneous photocatalysts with spatially segregated sites for fuel-evolution and the supply of electrons that is needed to sustain this process. We imagine that our photocatalysts will proove versatile and that with slight modification they will be able to harness solar energy for the manufacture of drugs and fine chemicals.

The aim of the proposed research is to provide the necessary knowledge to allow the development of a pre-prototype High Performance Vacuum Flat Plate Solar Thermal Collector with minimal materials content. The development of a thin evacuated solar collector offers new and exciting prospects for integrating solar collectors into building designs and for their use in medium temperature (100-200 Celsius) applications such as air conditioning or low temperature process heat. The research planned will develop technology for the effective utilisation of the solar energy resource and fits within EPSRC's Energy theme. Solar thermal energy is predicted to be a significant growth market with the potential to make a significant contribution to reducing fossil fuel use in the building energy sector. The research is targeted at providing new knowledge and techniques that will enable the advances in technology necessary for a step change in solar thermal collector performance to be realised and a range of new products and application areas developed. Such new products will encourage inward investment and lead to the creation of new companies that can contribute significantly to the transition to a low carbon society whilst maintaining and improving quality of life.

Reports concerning dwindling reserves of fossil fuels and concerns over fuel security are frequent news headlines. The rising costs of fuel are a daily reminder of the challenges faced by a global society with ever increasing energy demands. In this context it is perhaps surprising that so many of the renewable energy supplies available to us, namely, sunlight, winds and waves, remain largely untapped resources. This is mainly due to the challenges that exist in converting these energy forms into fuels from which energy can be released 'on demand' when we wish to play computer games, drive a car and so on. However, during plant photosynthesis fuels are made naturally from the energy in sunlight. Light absorption by the green chlorophyll pigments generates an energised electron that is directed, along chains of metal centres, to catalysts that make sugars. These sugars fuel us, and all animals, when their energy is released following digestion of a meal. However, using farmed plants to produce biofuels is controversial as agriculture is also required to feed the world. As a consequence, and inspired by natural processes, we propose to build a system for artificial photosynthesis. In essence, we wish to place tiny solar-panels on microbes in order to harness sunlight to drive the production of hydrogen - a fuel from which the technologies to release energy on demand are well-advanced. We will use dyes and semi-conductor particles as mechanically and chemically robust materials to capture the energy in sunlight and generate energised electrons. We will couple these particles to biology's version of conducting wires. These wires are made from heme proteins that span membranes that provide Nature's solution to compartmentalising water-filled chambers (i.e., the inside of the bacterium). The heme-wires are produced naturally by 'rock-breathing' microorganisms and after these wires have transferred the energised electrons across the membrane they will drive enzyme catalysis to produce hydrogen Our novel bio-mimetic photocatalysts will establish new principles for the design of homogeneous photocatalysts with spatially segregated sites for fuel-evolution and the supply of electrons that is needed to sustain this process. We imagine that our photocatalysts will proove versatile and that with slight modification they will be able to harness solar energy for the manufacture of drugs and fine chemicals.

The aim of the proposed research is to provide the necessary knowledge to allow the development of a pre-prototype High Performance Vacuum Flat Plate Solar Thermal Collector with minimal materials content. The development of a thin evacuated solar collector offers new and exciting prospects for integrating solar collectors into building designs and for their use in medium temperature (100-200 Celsius) applications such as air conditioning or low temperature process heat. The research planned will develop technology for the effective utilisation of the solar energy resource and fits within EPSRC's Energy theme. Solar thermal energy is predicted to be a significant growth market with the potential to make a significant contribution to reducing fossil fuel use in the building energy sector. The research is targeted at providing new knowledge and techniques that will enable the advances in technology necessary for a step change in solar thermal collector performance to be realised and a range of new products and application areas developed. Such new products will encourage inward investment and lead to the creation of new companies that can contribute significantly to the transition to a low carbon society whilst maintaining and improving quality of life.

The UK has a world class reputation for design and manufacture of space based technologies. A new National Space Academy has been launched this year to help boost the size and quality of the UK's science and engineering expertise. The proposal supports strongly The UK Space Directory, an organisation of eight groups representing and supporting the UK space community and including the Technology Strategy Board that state "the UK Space Industry has come together to propose an ambitious 20 year strategy to capture 10% of the global space market, £40 billion, by 2030 and in doing so create 100,000 UK jobs". The UK houses some of the leading companies in space applications such as; Inmarsat, Rolls Royce, Logica, Vega Space, Astrium, Qioptiq Space Technology and Surrey Satellite Technology Limited. The latter two companies strongly back the research detailed within this proposal and have both provided satements of support. This proposal seeks to offer an alternative PV technology for large area arrays and to be the first to report thin film cadmium telluride (CdTe) deposited directly onto toughened cerium-doped microsheet glass (CMG), explicitly targeting a significant increase in specific power by a step-change reduction of system weight. The Qioptiq Space Technology CMG microsheet glass is optimised to match the coefficient of thermal expansion (CTE) of gallium arsenide (GaAs) based space solar cells. With the CdTe CTE almost identical to that of GaAs the choice of CMG is ideal for the prevention of delamination under the severe thermal gradients to which space PV is exposed. This adventurous approach, using the CMG as both the radiation barrier and substrate, will be proven by characterisation of 5 x 5 cm2 deposited devices and finally scaled to 10 x 20 cm2 on the Centre for Solar Energy Research (CSER) pilot metalorganic chemical vapour deposition (MOCVD) system. This proposal has the content and vision to make a significant contribution to the UK's flourishing space industry. Key to the success of the project will be the dissemination and pathways to impact of the research outcomes; this will be ensured through regular reporting to and feedback from a steering group of potential exploiters-Industrial experts and through targeted press releases. This proposal offers UK research the chance to impact the space PV market either through licencing of the arising IP and more excitingly in the current economic climate through manufacture of the final product.

87% of global energy production in 2010 was derived from unsustainable fossil fuels and as energy consumption grows, we urgently need to move towards renewable, clean energy sources to ensure national and international energy security. Only ~36 kWh/day/person could realistically be generated by non-solar renewables, falling short of the global target for energy requirements of 80 kWh/day/person. Therefore, without relying on nuclear energy, we must ensure that solar energy fills the gap. To meet demand, we require as many on- and off-grid photovoltaic (PV) technologies as possible and development of sustainable, low-energy and material-light technologies should be prioritized. In this context, ink-jet printing organic semiconductors is highly attractive. Our project aims to use similar processing techniques to demonstrate a dramatic step change in PV efficiency to match that of transistors. Such a step change requires a global consortium such as ours, including world-leading chemists (USA), physicists/engineers (UK) and material scientists (Japan) as well as knowledge of market requirements (Organic PV company). We aim to tackle the whole PV cycle, from materials to exploitation. In particular concentrating on (i) sustainable approaches to organic semiconductor synthesis, potentially allowing organic PVs to be made out of bio waste such as corn stover, (ii) creating highly ordered PVs using novel adapted ink-jet printing and vapor-phase deposition (and comparing the two techniques) (iii) quantitatively characterising the single crystal structure, physics and morphology (iv) characterizing the finished PVs, including stability and lifetime. Constant feedback between the groups will be used to optimize the materials and processing techniques to develop revolutionary >10% efficient sustainable PVs.

The installation of photovoltaics today is largely evaluated in terms of quantity and the success of any market stimulation evaluated on the basis of how well the targets are met. This may cause significant problems for the national infrastructure and may lead to significant unnecessary costs for grid stabilisation. However, these factors are sometimes assessed too simplistically. When considering PV in a national context, it is also largely seen as a homogenous swarm of devices, i.e. all of them reacting rather similarly. This does not consider different orientations (system elevation determines the seasonal maximum, system orientation determines the daily maximum) or regional differences in the environmental conditions such as weather fronts passing in a matter of days over the country rather than instantaneously or the North experiencing a different weather front than the South; nationwide smoothing might very well limit the need for power control. Thus the overarching question in this proposal is 'How can we maximise the benefits and limit the costs for UK plc while having a vibrant PV market?'. The work is split into four topical areas (work-packages), which answer the four key questions: - How much PV are we likely to get with different policies and where is it likely to be installed? This will consider different socio-economic drivers, cost curves of PV and work on installation scenarios giving links to likely social background of installations, locations (as in regions) and quantities. - How much energy will this generate when and where? Based on current installations a model for the performance prediction of systems based on their post-code will be developed and validated against existing FIT data and other available monitoring data. A spin-off of this activity will be the widespread investigation of current installations, that will inform any further discussions on subsidy streams, and the potential for detailed condition monitoring with sparse data will be investigated. The model will be connected with the socio-economic drivers to stochastically locate future installations (using GIS and post-code classifiers), and estimate the energy yield for each system and aggregate to generation regions. This means that essentially for every system (which is today in the range of 400000 systems under the FIT) installed an hourly generation needs to be calculated, which will require very complex speed optimisation in the calculations. - How will it impact the infrastructure? Grid simulations will be carried out bottom up as well as top down to see if there are issues either locally or nationally with the proposed installations. This will allow the recommendation of further measures to strengthen infrastructure and will allow a cost-benefit analysis of PV technology to be undertaken. - What feedback will there be? Most policies will have effects on the questions above and thus it is foreseen that a feedback methodology will be created, calculating the costs/benefits for UK plc as well as evaluating likely responses of the policy makers and grid operators. The collaboration between the different groups will be tightly managed, so that the project outcomes interface well. Tools will be generated and made available with non-proprietary data for public use.

The aim of the proposed research is to provide the necessary knowledge to allow the development of a pre-prototype High Performance Vacuum Flat Plate Solar Thermal Collector with minimal materials content. The development of a thin evacuated solar collector offers new and exciting prospects for integrating solar collectors into building designs and for their use in medium temperature (100-200 Celsius) applications such as air conditioning or low temperature process heat. The research planned will develop technology for the effective utilisation of the solar energy resource and fits within EPSRC's Energy theme. Solar thermal energy is predicted to be a significant growth market with the potential to make a significant contribution to reducing fossil fuel use in the building energy sector. The research is targeted at providing new knowledge and techniques that will enable the advances in technology necessary for a step change in solar thermal collector performance to be realised and a range of new products and application areas developed. Such new products will encourage inward investment and lead to the creation of new companies that can contribute significantly to the transition to a low carbon society whilst maintaining and improving quality of life.