There is a wealth of data available to marine scientists to study the environment. These include measurements made from samples collected by boats, data from marine moorings, buoys and unmanned vessels as well as satellite data. For satellite data, this is now available at very high resolution so that a range of parameters and the intricate details of these in rivers, estuaries and the coast can be easily seen from space. Having all of these different sources of data available, makes it hard to analyse in a coherent, consistent and easily findable format. Data Cubes have been invented which are gridded and stacked arrays of different data sets, that can be interrogated easily and efficiently by scientists. The scientific organisation CSIRO in Australia has developed open data cubes, called AquaWatch Data Integration and Analysis System or ADIAS, that allows multiple users to easily interact with large archives of data. Through this platform, computer code, known as machine learning, can be used to turn some of the data sets into water quality parameters, to allow the assessment of whether coastal water is 'clean' or 'poor' quality. In both the western English Channel and eastern Australia, periodic flooding as a result of heavy rainfall is becoming more frequent. This is because the heating of inland water and the sea is causing more evapo-transpiration which results in high rainfall and then flooding. These flooding events can carry agricultural fertilisers, sewage effluent and, in some locations, heavy metals from mining tailing ponds from the rivers to the coast. This poses a risk to human health and to the environment through the deposition of high nutrients, suspended material, viruses and bacteria to the coast. This in turn can be deleterious to Seagrass beds and mud flats are important areas for depositing and drawing down CO2 from the atmosphere. These flooding events can be harmful to both seagrass beds and mud flats by blocking light that is normally available to seagrasses to photosynthesize and by introducing toxic material that disrupt mud flats. The project will measure the effect of flooding on seagrass beds and mud flats in Plymouth Sound, UK and the Fitzeroy River and adjacent coast of Australia. It will also provide maps of areas that are not effected by flooding to allow conservation groups to regenerate Seagrass beds. The information generated by the project will be a freely available to end-users to help the monitoring and management of water quality in the Plymouth Sound catchment. The project data and results will be showcased to interested parties through an end of project stakeholder event. The following groups will be invited to the event: Marine managers (FSA, DEFRA, CEFAS,), Fishery and Shellfishery end users (regional IFCA groups, OS-UK), Marine policy makers (DG-ENV, DG-MARE, OSPAR, ICES, OSPAR ICG COBAM Pelagic Habitats Expert Group), tourism and recreation groups (SAS, Sailing clubs, local anglers, SUP clubs) and Wildlife conservation and Environmental protection groups (UK Wildlife Trusts). Due to Brexit, collaboration with other European scientists is now restricted due to lack of funds. This project will facilitate knowledge and technology exchange between UK and Australia, now that EU collaboration is reduced.

The UK is committed to a target of reducing greenhouse gas emissions by 80% before 2050. With over 40% of fossil fuels used for low temperature heating and 16% of electricity used for cooling these are key areas that must be addressed. The vision of our interdisciplinary centre is to develop a portfolio of technologies that will deliver heat and cold cost-effectively and with such high efficiency as to enable the target to be met, and to create well planned and robust Business, Infrastructure and Technology Roadmaps to implementation. Features of our approach to meeting the challenge are: a) Integration of economic, behavioural, policy and capability/skills factors together with the science/technology research to produce solutions that are technically excellent, compatible with and appealing to business, end-users, manufacturers and installers. b) Managing our research efforts in Delivery Temperature Work Packages (DTWPs) (freezing/cooling, space heating, process heat) so that exemplar study solutions will be applicable in more than one sector (e.g. Commercial/Residential, Commercial/Industrial). c) The sub-tasks (projects) of the DTWPs will be assigned to distinct phases: 1st Wave technologies or products will become operational in a 5-10 year timescale, 2nd Wave ideas and concepts for application in the longer term and an important part of the 2050 energy landscape. 1st Wave projects will lead to a demonstration or field trial with an end user and 2nd Wave projects will lead to a proof-of-concept (PoC) assessment. d) Being market and emission-target driven, research will focus on needs and high volume markets that offer large emission reduction potential to maximise impact. Phase 1 (near term) activities must promise high impact in terms of CO2 emissions reduction and technologies that have short turnaround times/high rates of churn will be prioritised. e) A major dissemination network that engages with core industry stakeholders, end users, contractors and SMEs in regular workshops and also works towards a Skills Capability Development Programme to identify the new skills needed by the installers and operators of the future. The SIRACH (Sustainable Innovation in Refrigeration Air Conditioning and Heating) Network will operate at national and international levels to maximise impact and findings will be included in teaching material aimed at the development of tomorrow's engineering professionals. f) To allow the balance and timing of projects to evolve as results are delivered/analysed and to maximise overall value for money and impact of the centre only 50% of requested resources are earmarked in advance. g) Each DTWP will generally involve the complete multidisciplinary team in screening different solutions, then pursuing one or two chosen options to realisation and test. Our consortium brings together four partners: Warwick, Loughborough, Ulster and London South Bank Universities with proven track records in electric and gas heat pumps, refrigeration technology, heat storage as well as policy / regulation, end-user behaviour and business modelling. Industrial, commercial, NGO and regulatory resources and advice will come from major stakeholders such as DECC, Energy Technologies Institute, National Grid, British Gas, Asda, Co-operative Group, Hewlett Packard, Institute of Refrigeration, Northern Ireland Housing Executive. An Advisory Board with representatives from Industry, Government, Commerce, and Energy Providers as well as international representation from centres of excellence in Germany, Italy and Australia will provide guidance. Collaboration (staff/student exchange, sharing of results etc.) with government-funded thermal energy centres in Germany (at Fraunhofer ISE), Italy (PoliMi, Milan) and Australia (CSIRO) clearly demonstrate the international relevance and importance of the topic and will enhance the effectiveness of the international effort to combat climate change.

Australia

Economic development and population growth in Peninsular India have resulted in rapid changes to land-use, land-management and water demand which together are seriously impacting and degrading water resources. Urbanization, deforestation, agricultural intensification, shifts between irrigated agriculture and rain-fed crops, increased groundwater use, and the proliferation of small-scale surface water storage interventions, such as farm-level bunds (usually to conserve soil moisture in fields) and check-dams (to replenish local aquifers) all have contributed to significant changes in the hydrological functioning of catchments. The impact of such changes and interventions on local hydrological processes, such as streamflow, groundwater recharge and evapotranspiration, are poorly constrained, and our understanding of how these diverse local changes cumulatively impact water availability at the broader basin-scale is very limited. Focussing on the highly contentious inter-state Cauvery River basin (with an area of c.80,000 km2, the Cauvery is one of India's largest river basins) our study addresses the key scientific challenge of representing the many local, small-scale interventions in Peninsular India at larger scales. Using observations from established experimental catchments in both rural and urban settings, the project will first explore how changes in land-use, land-cover, irrigation practices and small-scale water management interventions locally affect hydrological processes. In tandem we will then develop novel upscaling methods to represent the improved process-understanding in models at the larger sub-basin (Kabini, ~10,000 km2) and basin (Cauvery) scales. In so doing, the project will demonstrate the capability to generically represent the cumulative impact of abundant small-scale changes in basin-wide integrated water resources management models. The impact of local-scale interventions will further be modelled alongside projections of population growth, climate- and land-use-change and water demand to assess future impacts on water security across the basin. Key stakeholders are involved throughout the different stages of the project to ensure that project outputs reflect their interests and concerns and provide useful input to their decision making.

3D Printing elicits tremendous excitement from a broad variety of industry - it offers flexible, personalised and on demand scalable manufacture, affording the opportunity to create new products with geometrical / compositional freedoms and advanced functions that are not possible with traditional manufacturing practices. 3D Printing progresses rapidly: for polymerics, we have seen significant advances in our ability to be able to manufacture highly functional structures with high resolution projection through developments in projection micro stereolithography, multimaterial ink jet printing and two photon polymerisation. There have also been exciting advances in volumetric 3DP with the emergence of Computational Axial Lithography and more recent work such as 'xolo'. Alongside these advances there has also been developments in materials, e.g., in the emergence of '4D printing' using responsive polymers and machine learning / AI on 3DP is beginning to be incorporated into our understanding. The impact of these advances is significant, but 3D printing technology is reaching a tipping point where the multiple streams of effort (materials, design, process, product) must be brought together to overcome the barriers that prevent mass take up by industry, i.e., materials produced can often have poor performance and it is challenging to match them to specific processes, with few options available to change this. Industry in general have not found it easy to adopt this promising technology or exploit advanced functionality of materials or design, and this is particularly true in the biotech industries who we target in this programme grant - there is the will and the aspiration to adopt 3D printing but the challenges in going from concept to realisation are currently too steep. A key challenge stymying the adoption of 3D printing is the ability to go from product idea to product realisation: each step of the workflow (e.g., materials, design, process, product) has significant inter-dependent challenges that means only an integrated approach can ultimately be successful. Industry tells us that they need to go significantly beyond current understanding and that manufacturing products embedded with advanced functionality needs the capability to quickly, predictably, and reliably 'dial up' performance, to meet sector specific needs and specific advanced functionalities. In essence, we need to take a bottom-up, scientific approach to integrate materials, design and process to enable us to produce advanced functional products. It is therefore critical we overcome the challenges associated with identifying, selecting, and processing materials with 3DP in order to facilitate wider adoption of this pivotal manufacturing approach, particularly within the key UK sectors of the economy: regenerative medicine, pharmaceutical and biocatalysis. Our project will consider four Research Challenges (RCs): PRODUCT: How can we exploit 3D printing and advanced polymers to create smart 21st Century products ready for use across multiple sectors? MATERIALS: How can we create the materials that can enable control over advanced functionality / release, that are 3D Printable? DESIGN: How can we use computational / algorithmic approaches to support materials identification / product design? PROCESS: How can we integrate synthesis, screening and manufacturing processes to shorten the development and translation pipeline so that we can 'dial up' materials / properties? By integrating these challenges, and taking a holistic, overarching view on how to realise advanced, highly functional bespoke 3D printed products that have the potential to transform UK high value biotechnology fields and beyond.