The motivation for this proposal is that the global reliance on fossil fuels is set to increase with the rapid growth of Asian economies and major discoveries of shale gas in developed nations. The strategic vision of the IDC is to develop a world-leading Centre for Industrial Doctoral Training focussed on delivering research leaders and next-generation innovators with broad economic, societal and contextual awareness, having strong technical skills and capable of operating in multi-disciplinary teams covering a range of knowledge transfer, deployment and policy roles. They will be able to analyse the overall economic context of projects and be aware of their social and ethical implications. These skills will enable them to contribute to stimulating UK-based industry to develop next-generation technologies to reduce greenhouse gas emissions from fossil fuels and ultimately improve the UK's position globally through increased jobs and exports. The Centre will involve over 50 recognised academics in carbon capture & storage (CCS) and cleaner fossil energy to provide comprehensive supervisory capacity across the theme for 70 doctoral students. It will provide an innovative training programme co-created in collaboration with our industrial partners to meet their advanced skills needs. The industrial letters of support demonstrate a strong need for the proposed Centre in terms of research to be conducted and PhDs that will be produced, with 10 new companies willing to join the proposed Centre including EDF Energy, Siemens, BOC Linde and Caterpillar, together with software companies, such as ANSYS, involved with power plant and CCS simulation. We maintain strong support from our current partners that include Doosan Babcock, Alstom Power, Air Products, the Energy Technologies Institute (ETI), Tata Steel, SSE, RWE npower, Johnson Matthey, E.ON, CPL Industries, Clean Coal Ltd and Innospec, together with the Biomass & Fossil Fuels Research Alliance (BF2RA), a grouping of companies across the power sector. Further, we have engaged SMEs, including CMCL Innovation, 2Co Energy, PSE and C-Capture, that have recently received Department of Energy and Climate Change (DECC)/Technology Strategy Board (TSB)/ETI/EC support for CCS projects. The active involvement companies have in the research projects, make an IDC the most effective form of CDT to directly contribute to the UK maintaining a strong R&D base across the fossil energy power and allied sectors and to meet the aims of the DECC CCS Roadmap in enabling industry to define projects fitting their R&D priorities. The major technical challenges over the next 10-20 years identified by our industrial partners are: (i) implementing new, more flexible and efficient fossil fuel power plant to meet peak demand as recognised by electricity market reform incentives in the Energy Bill, with efficiency improvements involving materials challenges and maximising biomass use in coal-fired plant; (ii) deploying CCS at commercial scale for near-zero emission power plant and developing cost reduction technologies which involves improving first-generation solvent-based capture processes, developing next-generation capture processes, and understanding the impact of impurities on CO2 transport and storage; (iimaximising the potential of unconventional gas, including shale gas, 'tight' gas and syngas produced from underground coal gasification; and (iii) developing technologies for vastly reduced CO2 emissions in other industrial sectors: iron and steel making, cement, refineries, domestic fuels and small-scale diesel power generatort and These challenges match closely those defined in EPSRC's Priority Area of 'CCS and cleaner fossil energy'. Further, they cover biomass firing in conventional plant defined in the Bioenergy Priority Area, where specific issues concern erosion, corrosion, slagging, fouling and overall supply chain economics.

The EPSRC Centre for Doctoral Training in Renewable Energy Northeast Universities (ReNU) is driven by industry and market needs, which indicate unprecedented growth in renewable and distributed energy to 2050. This growth is underpinned by global demand for electricity which will outstrip growth in demand for other sources by more than two to one (The drivers of global energy demand growth to 2050, 2016, McKinsey). A significant part of this demand will arise from vast numbers of distributed, but interconnected devices (estimated to reach 40 billion by 2024) serving sectors such as healthcare (for ageing populations) and personal transport (for reduced carbon dioxide emission). The distinctive remit of ReNU therefore is to focus on materials innovations for small-to-medium scale energy conversion and storage technologies that are sustainable and highly scalable. ReNU will be delivered by Northumbria, Newcastle and Durham Universities, whose world-leading expertise and excellent links with industry in this area have been recognised by the recent award of the North East Centre for Energy Materials (NECEM, award number: EP/R021503/1). This research-focused programme will be highly complementary to ReNU which is a training-focused programme. A key strength of the ReNU consortium is the breadth of expertise across the energy sector, including: thin film and new materials; direct solar energy conversion; turbines for wind, wave and tidal energy; piezoelectric and thermoelectric devices; water splitting; CO2 valorisation; batteries and fuel cells. Working closely with a balanced portfolio of 36 partners that includes multinational companies, small and medium size enterprises and local Government organisations, the ReNU team has designed a compelling doctoral training programme which aims to engender entrepreneurial skills which will drive UK regional and national productivity in the area of Clean Growth, one of four Grand Challenges identified in the UK Government's recent Industrial Strategy. The same group of partners will also provide significant input to the ReNU in the form of industrial supervision, training for doctoral candidates and supervisors, and access to facilities and equipment. Success in renewable energy and sustainable distributed energy fundamentally requires a whole systems approach as well as understanding of political, social and technical contexts. ReNU's doctoral training is thus naturally suited to a cohort approach in which cross-fertilisation of knowledge and ideas is necessary and embedded. The training programme also aims to address broader challenges facing wider society including unconscious bias training and outreach to address diversity issues in science, technology, engineering and mathematics subjects and industries. Furthermore, external professional accreditation will be sought for ReNU from the Institute of Physics, Royal Society of Chemistry and Institute of Engineering Technology, thus providing a starting point from which doctoral graduates will work towards "Chartered" status. The combination of an industry-driven doctoral training programme to meet identifiable market needs, strong industrial commitment through the provision of training, facilities and supervision, an established platform of research excellence in energy materials between the institutions and unique training opportunities that include internationalisation and professional accreditation, creates a transformative programme to drive forward UK innovation in renewable and sustainable distributed energy.

Marine mussels can survive the harsh marine environment at intertidal zones by anchoring themselves to various wet surfaces through adhesive plaques. Recent research progress has highlighted that, in addition to the interaction of protein-based chemistry at the adhesion sites, the unique adhesive structure of a mussel plaque plays an important role. Motivated by this natural phenomenon, the proposal aims to establish the knowledge on the underwater adhesive behaviours of mussel plaque-inspired anchoring systems for the applications of the offshore floating structures. The existing deep water anchoring systems such as drilled piles, suction anchors, and gravity anchors may be subject to various limitations with respect to the cost, the seabed conditions, and the installation; and can cause significant impact on the local marine environment. In addition, removal of these anchoring systems at the decommissioning phase could be difficult and expensive. In comparison, the plaque-like anchoring systems can potentially have the following ground-breaking features: (a) the adhesion at the anchoring systems can be switched on and off based on the requirement, which can lead to revolution in the design, construction, sustainability, and life cycle operation of the offshore floating structures, (b) by using advanced composite materials, the anchoring systems can be applied to a wide range of seabed conditions, i.e., rocky surfaces and soil surfaces, with minimum impact on the local marine environment ( i.e., no drilling or excavation on the seabed is required), and (c) the manufacturing and installation processes can be much more simplified, which leads to cost-effective solutions. The proposed research has the potential for substantial impact on various applications involving offshore floating structures such as offshore floating wind turbine (OFWT) systems, offshore oil rigs, tidal current turbine systems, and subsea infrastructure. Among these applications, it is worth noting that the requirement for developing novel OFWT systems has been highlighted by the offshore renewable energy sector and the recent governmental strategy- the UK Government has already committed to 1 GW of floating wind by 2030. The research will establish lab-scale prototypes of the mussel plaque-inspired anchoring systems. Using a combination of experimental techniques, adhesion theories and numerical modelling approaches, we will (1) evaluate the performance of the prototypes, and (2) examine the failure modes, detachment forces, traction force distributions and ductility under controlled external factors. The scaling up effect will be studied by examining the performance of the prototypes at different length scales. Investigation will also be conducted to examine the adhesion on different types of substrates, i.e., rock and soil. The optimised designs will be achieved via verified parameter studies, which can act as the guidance for engineering designs. Assessment in terms of likely cost and technical effectiveness will also be conducted based on the optimised designs.

The consortium submitting this proposal stems from the UK-China Network on Clean Energy Research that was setup by Prof. Haifeng Wang in January 2007 with 202k of financial support from EPSRC under its INTERACT 4 scheme. The goal of the Network is to disseminate and promote in China the research that the EPSRC SUPERGEN consortia have carried out in the UK. The proposed consortium thus extends the scope of the Network to the organisation of joint research between the UK SUPERGEN researchers and leading Chinese scientists of nationally funded research programmes. It is thus built on the basis of an existing link between members of the Network, Chinese universities and the Chinese Academy of Sciences. It also expands this collaboration to the two largest research institutes in power engineering in China: the China Electric Power Research Institute (EPRI) and the Nanjing Automatic Research Institute (NARI). All of the 9 UK investigators play a leading role in one or more of six SUPERGEN consortia that are sponsored by EPSRC to carry out focused collaborative programmes of research on various aspects of sustainable energy systems.Even though the power systems of the UK and China are at different stages of development, the issue of how to maintain security while accommodating an increasing amount of renewable generation capacity is an important concern in both countries. To achieve sustainable economic growth, these power systems will need to become more flexible and more robust. Engineers and scientists in the UK and China have complementary expertises in this area. Researchers in the UK have done a significant amount of work in recent years on renewable energy sources and their integration with the grid. On the other hand, security analysis and security enhancements techniques have been central R&D issues in China. Combining these expertises and facilitating a two-way transfer of knowledge would therefore clearly accelerate the pace of research on problems of common interest. We therefore propose to bring together the leading power system scientists from the UK SUPERGEN consortia and from the Chinese nationally funded projects to form a collaborative research team to study the sustainable security of power systems. Being able to assess and enhance the security of power systems is a key issue in the development of sustainable power systems. It is also a long-standing and complicated scientific and engineering problem with considerable breadth and depth. This proposal integrates 8 joint research projects that tackle the problem from the four most important perspectives, i.e., security analysis (JP1 and 2), renewable generation (JP7 and 8), protection (JP3 and 4) and control (JP4, 5 and 6). Two core projects, JP1 and 2, will develop new models and analytical methods for gaining a better understanding of power system sustainable security. They require input and support from JP7 and 8 on renewable generation and provide guidelines and tools to JP3, 4, 5 and 6 to enhance the sustainable security through power system protection and control. The contribution of the Chinese collaborators will be very significant as they have a strong experience with engineering practice and they have access to advanced experimental facilities that are not available in the UK. They have committed 4 post-doctoral researchers and 13 PhD students to work on the joint projects . These researchers are fully funded from sources in China. The Chinese collaborators have also pledged to seek further financial support in China to contribute to the Consortium if this application is successful. The proposed consortium has designed 3 schemes to ensure a two-way UK-China knowledge transfer through this collaboration. They are major dissemination events, UK-China training exchange and project meetings. The project will start on the 1st Oct. 2008 and run for 4 years.

The threat posed by tick-borne diseases (TBD) in temperate regions such as the UK is growing rapidly. Human exposure is often linked to woodlands that support high densities of tick vectors and key wildlife hosts of these pathogens, and are intensively used by people. Climate change and government policies to increase woodland connectivity and improve human recreational access are highly likely to increase risks of TBD in the UK. To mitigate this threat we need to better understand effects of landscape structure on the movement and habitat use of those wildlife species which are key hosts for ticks and zoonotic pathogens. We also need to understand how humans use landscapes, where they are most at risk of exposure to tick bites and whether exposure could be prevented by habitat and host management. Given recent shifts across Europe in the distributions of TBD and tick populations, it is also critical to understand how longer term climate and land use changes may affect the introduction, establishment and spread of TBDs. Bringing together researchers from ecology, epidemiology, public health, and social science, TICKSOLVE aims to address these gaps. We will provide evidence for optimal greening and woodland restoration policies that will maximise benefits to biodiversity and human wellbeing while minimising human risks from current and future tick-borne diseases by: 1. Bringing together key national and regional level actors in health, land and biodiversity policy that interact with landscapes and TBD systems, to frame key risk scenarios and feasible environmental interventions for TBDs. 2. Better understanding how landscape structure shapes wildlife host distribution, habitat selection and movements and consequently impacts on ticks and TBD risk combining ecological surveys, pathogen genetics and computer modelling 3. Mapping how people use woodland landscapes and how this interacts with risk of encountering infected ticks to identify high risk areas for human exposure 4. Modelling how potential environmental barriers and interventions could reduce human exposure, integrating this knowledge of ecological interactions across the landscapes 5. Predicting how changes in woodland area and climate and patterns of bird migration may change TBD risks in the future 6. Co-developing interventions to minimise current and future TBD risks with stakeholders and policymakers that are locally appropriate. The research will focus on three emerging pathogens that pose a risk to the UK. Firstly Lyme disease (LD) which is currently present in the UK and can cause long-term debilitation. Reported cases of LD have increased 10-fold since 2000, probably linked to an expanding distribution of its main tick vector, Ixodes ricinus. Secondly, tick-borne encephalitis (TBE) which has been recently detected in ticks in the UK with evidence of suspected human cases in 2019. TBE uses the same tick vector and can cause severe neurological damage and death with some 5,000 to 12,000 reported cases each year in mainland Europe. Thirdly, Crimean Congo Haemorrhagic Fever (CCHF), caused by a WHO priority pathogen CCHF virus, with epidemic potential, is expanding north-westward in Europe. It's tick vector, Hyalomma spp., was found recently on migratory birds arriving in the UK. The TICKSOLVE project platform and approach of co-developing research, models and risk communication materials with stakeholders, accounting for diverse land management priorities, will enable formulation of future-proofed woodland and greening policies that minimise risks of these diverse TBDs. Furthermore, engagement with key global partners and networks through webinars and meetings will facilitate transfer of TICKSOLVE inter-disciplinary approaches to other rapidly changing tick-borne disease systems worldwide.