Rufopoly is a participatory learning board game enabling players to undertake a journey through a fictitious rural urban fringe called RUFshire, answering questions and making decisions on development challenges and place-making; those answers then inform each player's vision for RUFshire. The encountered questions are determined by the roll of a die and based on primary data collected for a Relu project (2010-2012) about Managing Environmental Change at the Rural Urban Fringe. Rufopoly has been used extensively in early stages of projects and plans such as the pioneering Greater Birmingham and Solihull Local Enterprise Partnership spatial plan and has been used by government, EU project groups, local authorities, business, community groups, universities and schools. It has exposed audiences to issues associated with the delivery and trade-offs associated with planning and environmental issues at the fringe but crucially without the use of complex jargon. We believe that the full potential and impact of Rufopoly has yet to be fully realised. There are several reasons for this: 1. Rufopoly was developed towards the end of our Relu project as an unplanned output for a conference run by Relu in 2011 on 'Who Should run the Countryside?'. Its success prompted its inclusion as an output. 2. There were insufficient funds for it to be successfully tested and integrated with policy and practice communities to maximise its utility as a learning tool as this was never the original intention of the project. 3. It is currently presented as a one size fits all board game of a hypothetical place. More time is needed to explore the potential of Rufopoly to become a generic platform for stakeholders wishing to develop their own versions of the tool to meet their own needs and to fill a widely recognised gap in the effectiveness of participatory tools for improved decsion making. This knowledge exchange project addresses these deficiencies by drawing together the shared knowledge and previous experiences of designers and users of Rufopoly. This informs a series of interactive workshops in Wales, England and Scotland to identify how this kind of game-format can be enhanced into a more effective and multifunctional tool. This will help extend and embed the impact for a range of policy and practice partners in the form of a Rufopoly Resource Kit. By working collaboratively with end users we can identify how Rufopoly can be reconfigured across different user groups and organisations in tune with their agendas and needs. There are four stages to this project: WP1: Review and learn lessons from previous Rufopoly experiences. This involves (1) an assessment of the actual results and findings from past games that were written up and the results analysed. (2) critical assessments of the strengths and weaknesses of Rufopoly from facilitators and core participants. We will draw priamirly from our UK experiences but are also able to secure insights from the international adaptations of Rufopoly from Nebraska (November 2013) and Sweden (2014). WP2: Conduct a series of interactive workshops with different policy and practice audiences. These workshops will be held in England, Scotland and Wales using members of the research team and other participants. The purpose of these workshops is to (1) share results of WP1; (2) assess how the tool could be reconfigured to address the principla needs and challenges facing participants; and (3) prioritise feasible options for a Rufopoly Resource Kit. WP3: Using WP1 and WP2 outcomes, we will design and trial (across our team) the Rufopoly 'Mk2' resource kit and associated materials/guidance. WP4: Launch the Rufopoly Resource Kit and guidance in a live streamed global workshop event. This would; reveal the basic resource kit as co-designed by the team and enable testers of the resource kit to share their experiences maximising knowledge exchange and its range of potential applications.

NCEO's NPG activity delivers expert scientific, technical and operational advice on EO-related policies and services to government departments and agencies. NCEO works particularly with the UK Space Agency and Defra, with a growing liaison with BEIS Climate Team. Advice covers scientific and technical insight; appraisal and review, reports; organisation of technical working groups and science surveys; and inputs to statements. Our expected activities are to provide: 1. Advice by the NCEO Director and senior staff to the UK Space Agency regarding UK Space Policy, including the subscriptions to European Space Agency programmes, Industrial Strategy and spectrum usage. 2. Advice to the Defra group, including Chief Scientific Advisor's Innovation programme regarding the application of space-based Earth Observation to environmental policy and services, including advice on the EU Copernicus programme, the Defra EO Centre of Excellence and the emerging UK Government Earth Observation Service. 3. Ad hoc advice to other government departments and agencies regarding the suitability of EO for particular applications and ways of overcoming particular challenges (e.g. supply of analysis ready data, utility of data cubes), for example to the BEIS Climate Team. 4. Coordination of advice to UK government (Defra, UK Space Agency) and technical expert activities related to the international Group on Earth Observations (GEO) and the Committee on Earth Observation Satellites (CEOS), including high level briefings. The aim is that UK organisations can contribute to and benefit strongly from developments in the international community, a current government priority. Societal and public benefit are important drivers for these global engagements.

Reducing carbon emissions and securing energy supplies are crucial international goals to which energy demand reduction must make a major contribution. On a national level, demand reduction, deployment of new and renewable energy technologies, and decarbonisation of the energy supply are essential if the UK is to meet its legally binding carbon reduction targets. As a result, this area is an important theme within the EPSRC's strategic plan, but one that suffers from historical underinvestment and a serious shortage of appropriately skilled researchers. Major energy demand reductions are required within the working lifetime of Doctoral Training Centre (DTC) graduates, i.e. by 2050. Students will thus have to be capable of identifying and undertaking research that will have an impact within their 35 year post-doctoral career. The challenges will be exacerbated as our population ages, as climate change advances and as fuel prices rise: successful demand reduction requires both detailed technical knowledge and multi-disciplinary skills. The DTC will therefore span the interfaces between traditional disciplines to develop a training programme that teaches the context and process-bound problems of technology deployment, along with the communication and leadership skills needed to initiate real change within the tight time scale required. It will be jointly operated by University College London (UCL) and Loughborough University (LU); two world-class centres of energy research. Through the cross-faculty Energy Institute at UCL and Sustainability Research School at LU, over 80 academics have been identified who are able and willing to supervise DTC students. These experts span the full range of necessary disciplines from science and engineering to ergonomics and design, psychology and sociology through to economics and politics. The reputation of the universities will enable them to attract the very best students to this research area.The DTC will begin with a 1 year joint MRes programme followed by a 3 year PhD programme including a placement abroad and the opportunity for each DTC student to employ an undergraduate intern to assist them. Students will be trained in communication methods and alternative forms of public engagement. They will thus understand the energy challenges faced by the UK, appreciate the international energy landscape, develop people-management and communication skills, and so acquire the competence to make a tangible impact. An annual colloquium will be the focal point of the DTC year acting as a show-case and major mechanism for connection to the wider stakeholder community.The DTC will be led by internationally eminent academics (Prof Robert Lowe, Director, and Prof Kevin J Lomas, Deputy Director), together they have over 50 years of experience in this sector. They will be supported by a management structure headed by an Advisory Board chaired by Pascal Terrien, Director of the European Centre and Laboratories for Energy Efficiency Research and responsible for the Demand Reduction programme of the UK Energy Technology Institute. This will help secure the international, industrial and UK research linkages of the DTC.Students will receive a stipend that is competitive with other DTCs in the energy arena and, for work in certain areas, further enhancement from industrial sponsors. They will have a personal annual research allowance, an excellent research environment and access to resources. Both Universities are committed to energy research at the highest level, and each has invested over 3.2M in academic appointments, infrastructure development and other support, specifically to the energy demand reduction area. Each university will match the EPSRC funded studentships one-for-one, with funding from other sources. This DTC will therefore train at least 100 students over its 8 year life.

Seabed sediment represents a significant sink for carbon (C) and represents a major natural asset. Bottom-trawl fishing provides a quarter of global seafood but is also the most extensive anthropogenic physical disturbance to sediment C stocks with recent evidence suggesting that seabed disturbance could result in significant greenhouse gas release from the seabed and to the atmosphere. There are major uncertainties in our understanding of the effect of disturbance on seabed C stores and air/sea CO2 fluxes (in both magnitude and direction). Consequently, the impact of seabed disturbances on C are largely unquantified and currently unregulated. This project will determine how the disturbance associated with bottom trawling modifies C storage, cycling and air/sea CO2 fluxes. For the first time, the impact of trawling on sediment-water and air-sea CO2 exchange will be assessed holistically, providing essential guidance on seabed activity management policies that mitigate climate impacts and help achieve net-zero. The project will answer all four questions defined in the Highlight Topic call: How do fishing gear, trawling frequency and the sedimentary environment affect the potential for marine sediments to act as a net source of CO2? How does C resuspended due to trawling modulate seawater chemistry and what is the fate of the resuspended C? How do horizontal and vertical mixing, water column production and respiration affect the potential for trawl-driven biogeochemical change to result in impacts on air-sea exchanges? Will management interventions result in the reduction of C loss and CO2 emissions and recovery of seabed sediment C stocks? The project comprises of 4 integrated work packages (WPs) that directly address these 4 questions. WP1 will characterise sediment pore waters and quantify the stocks of POC and PIC in the sediment and will identify how trawl gears affect the fluxes of C under different environmental settings. WP2 will characterise changes in the water column and suspended C and sediment and establish its fate in the water column after trawl disturbance. WP3 will quantify the exchange of sub-surface trawl plumes with the surface mixed layer and resultant seawater CO2 and air/sea fluxes. WP1-3 will generate novel insights about the mechanisms through which disturbance affects C fluxes and transformations. A focussed campaign of ship-based experiments will be used to inform and improve model assessments. We selected four representative sites that allow understanding of processes in contrasting environmental settings. The 3 integrated WPs will inform and improve models, which will be used to upscale and extend the spatial and temporal assessment of trawling impacts. These spatial assessments will feed into WP4, which will evaluate and identify the most effective seabed C stock management measures in collaboration with stakeholders from policy, fishing industry, eNGOs and green finance. This research will link processes, impact and mitigation of CO2 emissions due to seabed disturbance. The outcomes of the research will inform environmental solutions by avoiding emissions from seabed sediments while maintaining food production, which sits at the centre of the NERC, UKRI, DEFRA and UK strategies for clean growth and achieving net-zero. This project will make a step change in our understanding of how trawling impacts C dynamics in shelf seas and will diminish the risk of under-valuing natural climate regulation by facilitating cost-benefit analysis and risk assessments.

The most abundant form of litter in the marine environment is plastic, and the negative and detrimental consequences of plastic debris on fish, reptiles, birds and mammals are well documented. The hard surface of waterborne plastic provides an ideal environment for the formation of biofilm for opportunistic microbial colonisers; however, our knowledge of how microorganisms interact with microplastics and alter the dispersal behaviour of marine plastics in the environment is a significant research gap. Biofilm at the interface between the plastic surface and the environment has been termed the 'Plastisphere', and although plastics are extremely resistant to decay, variability in composition determines their specific buoyancy and surface rugosity, which will dictate the extent of microbial colonisation and their ability for long distance dispersal. Furthermore, because plastic debris can persist in the marine environment longer than natural substrates, e.g. feathers and wood, it offers an opportunity for the wider dissemination of pathogenic and harmful microorganisms. Microplastics from clothes, cosmetics and sanitary products are now common constituents of sewage systems and they frequently bypass the screening mechanisms designed to remove larger waste items from being exported to coastal waters. Microplastics entering aquatic systems from waste water treatment plants (WWTPs) come in close contact with human faeces, hence providing significant opportunity for colonisation by faecal indicator organisms (FIOs) and a range of human bacterial pathogens. Importantly however, there have never been any studies investigating the ability of enteric viruses binding to microplastics (or binding to the biofilm on the plastic surface), and this now needs critical evaluation in order to understand this potentially novel mechanism for the environmental dispersal of enteric viruses. Furthermore, there is growing evidence that the plastisphere can promote gene exchange, and so determining the potential of plastisphere biofilms for providing the surface for anti-microbial resistance (AMR) gene transfer is of the utmost importance. There is currently a lack of fundamental understanding about the mechanisms by which microorganisms, particularly pathogenic bacteria and viruses, can "hitchhike" on microplastic particles and be transported to beaches, bathing waters, shellfish harvesting waters and high benthic diversity zones. Consequently, it is not yet possible to determine the risk from these potential pathways, or establish environmental monitoring guidelines for informing future policy or environmental regulation. Therefore, the novelty of this project is to quantify the processes that are occurring within the plastisphere, and understand the potential for the vectoring of pathogenic viruses and bacteria. Previous research on chemical co-pollutants present on plastics often fails to consider the likely impacts of plastisphere communities. Microplastics in the environment are potential vectors for these chemicals, which often desorb when ingested by marine species, and can accumulate in the food chain. Microbes in the plastisphere may either mitigate this problem through biodegradation, or enhance it by increased biofilm binding; however, most laboratory-based studies are carried out with pristine non-colonised plastics, and ignore the pivotal role the plastisphere plays on defining the risk of microplastics in the environment. By understanding the multi-pollutant and multi-scale effects of microplastics, the "Plastic Vectors Project" will help to establish a more accurate risk assessment of microplastics by taking into consideration the effects of harmful plastic-associated microbes together with chemical co-pollutants. Therefore, the "Plastic Vectors Project" aims to quantify the significance and function of microbes in the 'plastisphere', and will deliver feasible solutions for reducing these multi-pollutant risks