Energy networks are vitally important enablers for the UK energy sector and therefore UK industry and society. The energy trilemma (energy security, environmental impact and social cost) presents many complex interconnected challenges which reach beyond the UK and have huge relevance internationally. These challenges vary considerably from region to region, and change as a result of technology and society changes. Therefore, the planning, design and operation of energy networks needs to be revisited and optimised. Current energy networks research does not fully embrace a whole systems approach and is therefore not developing a deep enough understanding of the interconnected and interdependent nature of energy network infrastructure. The Supergen Energy Networks Hub will provide leadership, a core research programme and mechanisms/funding for the energy networks community to grow and come together to develop this deeper understanding and explore opportunities to shape energy networks which are fit for the future. The research component of the Hub's activities comprises an interconnected and complementary series of work packages. The work packages are: WP1: Understanding, Shaping and Challenging; WP2: Energy Network Infrastructure; WP3: ICT and Data; WP4: Policy and Society; WP5: Markets and Regulation; WP6: Risk and Uncertainty. WP1 incorporates a co-evolutionary approach and brings the other work packages together in a structured way. WP2 is the backbone of the research, dealing with the physical infrastructure in a multi vector manner from the outset. WP3 to WP6 deal with aspects of energy networks that cut across, and are equally valid, for all vectors and have the ability to integrate and modernise network infrastructures. All work packages will consider both planning and design as well as operational aspects. Experimental work and demonstrators will be essential to progress in energy networks research and the Hub will bring these facilities to bear through WP1. The Hub will engage with the energy networks communities throughout the research programme, to ensure that the work is informed by best practice and that the findings are widely visible and understood. The main objectives of the communication and engagement activities will be to ensure the energy networks academic community are connected and coherent, and that their work has a high profile and deep level of understanding in the relevant Industrial, Governmental and Societal communities both nationally and internationally. This will maximise the chances of high impact outcomes in the energy networks space as well as promoting energy networks as an exciting and dynamic area to carry out research, thus attracting the brightest minds to get involved. Communication and engagement activities will be a constant feature of the Hub and will be particularly energetic during the first twelve months in order to rapidly establish a brand, and an open and supportive culture within the relevant communities. Engagement activities will as far as possible be carried out in conjunction with other key organisations in the energy space, to maximise the value of the engagement activities. The Hub aims to become a beacon for equality, diversity and inclusion. Our mission is to enhance equality of opportunity and create a positive, flourishing, safe and inclusive environment for everyone associated with the Hub, from staff, students, Advisory Board members and general Hub representation (at conferences, workshops and reviews). We recognise the need and the challenges to support early career researchers, and improve the balance of protected characteristics across the entire Hub community, such as race or ethnicity, gender reassignment, disability, sex, sexual orientation, age, religion or belief, pregnancy or maternity status, marital status or socio-economic background.

Background: The UK has legally-binding targets to reduce its greenhouse gas (GHG) emissions and increase the use of renewable sources of energy. There is a target of reducing 80% of GHG emissions by 2050, compared to the 1990 level, as well as interim targets to reduce emissions and increase the use of renewable energy for 2020 and 2030. The electrification of heat along with a large utilisation of renewable sources for power generation are considered as a solution to meet the emission and renewable targets for UK. However, these will result in variability and uncertainty in electricity supply as well as substantially higher peaks of electricity demand. If these issues are to be addressed through a "predict and provide" approach (i.e. building more capacity for back-up power generation, transmission and distribution infrastructure), significantly high costs will be incurred. These costs can be reduced by employing flexibility technologies enabling peak shaving and supporting electricity demand and supply balancing. A study for the UK Government estimates that deploying flexibility technologies (electricity storage, electricity demand response, flexible power station operation and international interconnectors) in the Great Britain power system can save up to £40bn of the power system costs to 2050 [1]. In addition to the flexibility offered by battery storage which requires massive investment to be realised, there already exist substantial energy storage and demand response potentials within heat and gas systems which can be exploited to support the operation of electricity system and facilitate a cost-effective transition to a low carbon and resilient energy system. To achieve this, efficient integration of electricity, heat and gas systems across different scales is required. For example, the correct integration of the electricity and heating sectors through optimal operation of "power-to-heat" technologies and thermal storage (in the form of hot water tanks, and also as thermal storage using the thermal inertia of networks and buildings) enables a shift in electricity demand required for heating. Research aims: This research will (i) identify and quantify potential flexibility that is inherent in gas and heat systems (e.g. gas and thermal storage and demand response capability) across various scales (i.e. buildings, district heating system, national gas transmission systems), (ii) optimise the provision of flexibility from gas and heat systems to support the operation of a low carbon power system, and (iii) develop modelling tools and methodologies to inform energy policy and provide technical and regulatory recommendations to enable maximum exploitation of flexibility through energy systems integration. Work Programme: WP1. Project management, engagement and exploitation WP2. Quantification of flexibility requirement in a low carbon power system WP3. Characterisation and quantification of flexibility technologies in heat and gas sectors WP4. Optimisation of integrated energy systems for flexibility provision WP5. Agent-based game-theoretic model to investigate interactions between key players in integrated energy systems WP6. Identifying real world barriers to exploitation of flexibility from energy systems integration References [1] Carbon Trust, "An analysis of electricity system flexibility for Great Britain," https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/568982/An_analysis_of_electricity_flexibility_for_Great_Britain.pdf , 2016.

EPSRC Centre for Doctoral Training in Resilient Decarbonised Fuel Energy Systems Led by the University of Nottingham, with Sheffield and Cardiff SUMMARY This Centre is designed to support the UK energy sector at a time of fundamental change. The UK needs a knowledgeable but flexible workforce to deliver against this uncertain future. Our vision is to develop a world-leading CDT, delivering research leaders with broad economic, societal and contextual awareness, having excellent technical skills and capable of operating in multi-disciplinary teams covering a range of roles. The Centre builds on a heritage of two successful predecessor CDTs but adds significant new capabilities to meet research needs which are now fundamentally different. Over 80% of our graduates to date have entered high-quality jobs in energy-related industry or academe, showing a demand for the highly trained yet flexible graduates we produce. National Need for a Centre The need for a Centre is demonstrated by both industry pull and by government strategic thinking. More than forty industrial and government organisations have been consulted in the shaping and preparation of this proposal. The bid is strongly aligned with EPSRC's Priority Area 5 (Energy Resilience through Security, Integration, Demand Management and Decarbonisation) and government policy. Working with our partners, we have identified the following priority research themes. They have a unifying vision of re-purposing and re-using existing energy infrastructure to deliver rapid and cost-effective decarbonisation. 1. Allowing the re-use and development of existing processes to generate energy and co-products from low-carbon biomass and waste fuels, and to maximise the social, environmental and economic benefits for the UK from this transition 2. Decreasing CO2 emissions from industrial processes by implementation of CCUS, integrating with heat networks where appropriate. 3. Assessing options for the decarbonisation of natural gas users (as fuel or feedstock) in the power generation, industry and domestic heating system through a combination of hydrogen enhancement and/or CO2 capture. Also critical in this theme is the development of technologies that enable the sustainable supply of carbon-lean H2 and the adoption of H2 or H2 enriched fuel/feedstock in various applications. 4. Automating existing electricity, gas and other vector infrastructure (including existing and new methods of energy storage) based on advanced control technologies, data-mining and development of novel instrumentation, ensuring a smarter, more flexible energy system at lower cost. Training Our current Centre operates a training programme branded 'exemplary' by our external examiner and our intention is to use this as solid basis for further improvements which will include a new technical core module, a module on risk management and enhanced training in inclusivity and responsible research. Equality, Diversity and Inclusion Our current statistics on gender balance and disability are better than the EPSRC mean. We will seek to further improve this record. We are also keen to demonstrate ED&I within the Centre staff and our team also reflects a diversity in gender, ethnicity and experience. Management and Governance Our PI has joined us after a career conducting and managing energy research for a major energy company and led development of technologies from benchtop to full-scale implementation. He sharpens our industrial focus and enhances an already excellent team with a track record of research delivery. One Co-I chairs the UoN Ethics Committee, ensuring that Responsible Innovation remains a priority. Value for Money Because most of the Centre infrastructure and organisation is already in place, start-up costs for the new centre will be minimal giving the benefit of giving a new, highly refreshed technical capability but with a very low organisational on-cost.

Energy networks are vitally important enablers for the UK energy sector and therefore UK industry and society. The energy trilemma (energy security, environmental impact and social cost) presents many complex interconnected challenges which reach beyond the UK and have huge relevance internationally. These challenges vary considerably from region to region, and change as a result of technology and society changes. Therefore, the planning, design and operation of energy networks needs to be revisited and optimised. Current energy networks research does not fully embrace a whole systems approach and is therefore not developing a deep enough understanding of the interconnected and interdependent nature of energy network infrastructure. The Supergen Energy Networks Hub will provide leadership, a core research programme and mechanisms/funding for the energy networks community to grow and come together to develop this deeper understanding and explore opportunities to shape energy networks which are fit for the future. The research component of the Hub's activities comprises an interconnected and complementary series of work packages. The work packages are: WP1: Understanding, Shaping and Challenging; WP2: Energy Network Infrastructure; WP3: ICT and Data; WP4: Policy and Society; WP5: Markets and Regulation; WP6: Risk and Uncertainty. WP1 incorporates a co-evolutionary approach and brings the other work packages together in a structured way. WP2 is the backbone of the research, dealing with the physical infrastructure in a multi vector manner from the outset. WP3 to WP6 deal with aspects of energy networks that cut across, and are equally valid, for all vectors and have the ability to integrate and modernise network infrastructures. All work packages will consider both planning and design as well as operational aspects. Experimental work and demonstrators will be essential to progress in energy networks research and the Hub will bring these facilities to bear through WP1. The Hub will engage with the energy networks communities throughout the research programme, to ensure that the work is informed by best practice and that the findings are widely visible and understood. The main objectives of the communication and engagement activities will be to ensure the energy networks academic community are connected and coherent, and that their work has a high profile and deep level of understanding in the relevant Industrial, Governmental and Societal communities both nationally and internationally. This will maximise the chances of high impact outcomes in the energy networks space as well as promoting energy networks as an exciting and dynamic area to carry out research, thus attracting the brightest minds to get involved. Communication and engagement activities will be a constant feature of the Hub and will be particularly energetic during the first twelve months in order to rapidly establish a brand, and an open and supportive culture within the relevant communities. Engagement activities will as far as possible be carried out in conjunction with other key organisations in the energy space, to maximise the value of the engagement activities. The Hub aims to become a beacon for equality, diversity and inclusion. Our mission is to enhance equality of opportunity and create a positive, flourishing, safe and inclusive environment for everyone associated with the Hub, from staff, students, Advisory Board members and general Hub representation (at conferences, workshops and reviews). We recognise the need and the challenges to support early career researchers, and improve the balance of protected characteristics across the entire Hub community, such as race or ethnicity, gender reassignment, disability, sex, sexual orientation, age, religion or belief, pregnancy or maternity status, marital status or socio-economic background.

Across the UK, 80% of the heating in buildings and industries is generated using natural gas [1]. According to the Department for Business, Energy & Industry Strategy, transitioning to electricity, hydrogen and bioenergy have the potential to make a significant contribution toward low carbon heating. With respect to hydrogen, one potential approach is to use the existing natural gas distribution grid to transport hydrogen. In this research we explore a zero-carbon emission ICHP energy network concept for decarbonising heating and cooling through the production, distribution and utilisation of hydrogen. At the national scale, existing gas grid infrastructure would be modified and used to deliver natural gas and hydrogen produced from clean sources to distributed ICHP energy centres across the UK. At the local scale, intelligent thermal networks, would convert this hydrogen and distribute its energy as electricity, heating or cooling across urban areas in localised industry and residential networks. Furthermore, ICHP energy centres would also offer additional flexibility, resilience etc. and provide an opportunity to integrate transport energy services through the provision of hydrogen fuelling and electric vehicle fast charging. The project will be focus on investigating the role and value of the ICHP concept in supporting cost effective heat sector decarbonisation and transition to low carbon whole-energy system. The aim of the proposal will enable in depth assess of the role of ICHP concept from whole system perspective by: - Quantifying the techno-economic value of ICHP based heat sector decarbonisation in the whole-energy system context, considering infrastructure investment and operating costs for different carbon emissions targets in short, medium and long term. - Identifying and quantifying the benefits of flexibility options (i.e., energy storage, demand side response, hydrogen-based flexible gas plants). - Assessing the role of ICHP paradigm in enhancing the electricity system resiliency, given that the extreme weather conditions should be considered when planning low carbon energy system. Outputs will be technical evidence of the potential of the technology for stakeholders across the whole system (policy, national, local and consumers).