Anthocyanins (ANC) are natural pigments found in fruits, vegetables and flowers. Interest in ANC has increased substantially recently as the food and cosmetics industries crave for natural ingredients to replace synthetic dyes. However, use of ANC in the foods and cosmetics presents a number of challenges including stability, compatibility with the food or cosmetic product, and achieving the desired colour. One option for improving stability and application compatibility is modifying the pigments. In our previous research we demonstrated that modifying ANC with natural fatty acids was possible, using enzymes to join the two compounds together. This follow-on project will improve these methods to develop new, high-value, naturally-derived colorants on a scale that is commercially viable for food and cosmetic applications. This project is likely to result in the commercialisation of new products with economic impact in different industrial fields benefiting the whole value chain.

The Collaborative Research & Development (R&D) Partnership project will work with the Fashion Textiles and related Technology (FTT) industry in order develop research-led solutions to business growth, technological and consumer change. This will include working closely with small firms who make up the vast majority (80+%) of the sector, in fashion design, designer-making, manufacturing, retail and in related services that are fed by the fashion & textiles sector, e.g. events, interiors, publishing, performing arts, media and other creative services, as well as a wide range of textiles applications in manufacturing, medical and product design. The research will be delivered by a partnership between several universities led by the University of the Arts London, who together specialise in fashion and textiles design, business, manufacture and marketing, including specialist research centres in sustainable fashion and circular design, sustainable prosperity, materials and textiles manufacturing, in London, Leeds, Loughborough and Cambridge. The R&D project will be based around the East London Fashion & Textiles cluster and the connected production growth corridors of the Thames Gateway and Lea Valley/M11 (London-Cambridge) where opportunities for FTT workspace and manufacturing expansion are evident. The R&D work programme will include short and longer term research projects and enterprise support with small firms/SMEs to identify and develop solutions to the growth of their business, products and markets and related skills needs; work with larger fashion brands to develop more sustainable products through innovative design, manufacture and waste processing; research consumer experience and needs in material/fashion brands and retailing, including the future place of high street retail, store design and online markets; test new and existing synthetic and natural materials for new product development; and explore markets for more sustainable UK fibres/chemical processes and opportunities for regional UK textile production. The R&D programme, which will be co-designed with FTT companies and industry associations, will also identify the related skill and training needs which accompany the economic and technological challenges facing the FTT industry, and design through the university partners and other training providers (e.g. FE Colleges) and enterprise support organisations, new and novel training and Continuing Professional Development programmes.

The CDT in Molecules to Product addresses an overarching concern articulated by industry operating in the area of complex chemical products. It centres on the lack of a pipeline of doctoral graduates who understand the cross-scale issues that need to be addressed within the chemicals continuum. Translating their concern into a vision, the focus of the CDT is to train a new generation of research leaders with the skills and expertise to navigate the journey from a selected molecule or molecular system through to the final product that delivers the desired structure and required performance. To address this vision, three inter-related Themes form the foundation of the CDT - Product Functionalisation and Performance, Product Characterisation, and Process Modelling between Scales. More specifically, industry has identified a real need to recruit PGR graduates with the interdisciplinary skills covered by the CDT research and training programme. As future leaders they will be instrumental in delivering enhanced process and product understanding, and hence the manufacture of a desired end effect such as taste, dissolution or stability. For example, if industry is better informed regarding the effect of the manufacturing process on existing products, can the process be made more efficient and cost effective through identifying what changes can be made to the current process? Alternatively, if there is an enhanced understanding of the effect of raw materials, could stages in the process be removed, i.e. are some stages simply historical and not needed. For radically new products that have been developed, is it possible through characterisation techniques to understand (i) the role/effect of each component/raw material on the final product; and (ii) how the product structure is impacted by the process conditions both chemical and mechanical? Finally, can predictive models be developed to realise effective scale up? Such a focus will assist industry to mitigate against wasted development time and costs allowing them to focus on products and processes where the risk of failure is reduced. Although the ethos of the CDT embraces a wide range of sectors, it will focus primarily on companies within speciality chemicals, home and personal care, fast moving consumer goods, food and beverage, and pharma/biopharma sectors. The focus of the CDT is not singular to technical challenges: a core element will be to incorporate the concept of 'Education for Innovation' as described in The Royal Academy of Engineering Report, 'Educating engineers to drive the innovation economy'. This will be facilitated through the inclusion of innovation and enterprise as key strands within the research training programme. Through the combination of technical, entrepreneurial and business skills, the PGR students will have a unique set of skills that will set them apart from their peers and ultimately become the next generation of leaders in industry/academia. The training and research agendas are dependent on strong engagement with multi-national companies, SMEs, start-ups and stakeholders. Core input includes the offering, and supervision of research projects; hosting of students on site for a minimum period of 3 months; the provision of mentoring to students; engagement with the training through the shaping and delivery of modules and the provision of in-house courses. Additional to this will be, where relevant, access to materials and products that form the basis of projects, the provision of software, access to on-site equipment and the loan of equipment. In summary, the vision underpinning the CDT is too big and complex to be tackled through individual PhD projects - it is only through bringing academia and industry together from across multiple disciplines that a solution will be achievable. The CDT structure is the only route to addressing the overarching vision in a structured manner to realise delivery of the new approach to product development.

This world-leading Centre for Doctoral Training in Bioenergy will focus on delivering the people to realise the potential of biomass to provide secure, affordable and sustainable low carbon energy in the UK and internationally. Sustainably-sourced bioenergy has the potential to make a major contribution to low carbon pathways in the UK and globally, contributing to the UK's goal of reducing its greenhouse gas emissions by 80% by 2050 and the international mitigation target of a maximum 2 degrees Celsius temperature rise. Bioenergy can make a significant contribution to all three energy sectors: electricity, heat and transport, but faces challenges concerning technical performance, cost effectiveness, ensuring that it is sustainably produced and does not adversely impact food security and biodiversity. Bioenergy can also contribute to social and economic development in developing countries, by providing access to modern energy services and creating job opportunities both directly and in the broader economy. Many of the challenges associated with realising the potential of bioenergy have engineering and physical sciences at their core, but transcend traditional discipline boundaries within and beyond engineering. This requires an effective whole systems research training response and given the depth and breadth of the bioenergy challenge, only a CDT will deliver the necessary level of integration. Thus, the graduates from the CDT in Bioenergy will be equipped with the tools and skills to make intelligent and informed, responsible choices about the implementation of bioenergy, and the growing range of social and economic concerns. There is projected to be a large absorptive capacity for trained individuals in bioenergy, far exceeding current supply. A recent report concerning UK job creation in bioenergy sectors concluded that there "may be somewhere in the region of 35-50,000 UK jobs in bioenergy by 2020" (NNFCC report for DECC, 2012). This concerned job creation in electricity production, heat, and anaerobic digestion (AD) applications of biomass. The majority of jobs are expected to be technical, primarily in the engineering and construction sectors during the building and operation of new bioenergy facilities. To help develop and realise the potential of this sector, the CDT will build strategically on our research foundation to deliver world-class doctoral training, based around key areas: [1] Feedstocks, pre-processing and safety; [2] Conversion; [3] Utilisation, emissions and impact; [4] Sustainability and Whole systems. Theme 1 will link feedstocks to conversion options, and Themes 2 and 3 include the core underpinning science and engineering research, together with innovation and application. Theme 4 will underpin this with a thorough understanding of the whole energy system including sustainability, social, economic public and political issues, drawing on world-leading research centres at Leeds. The unique training provision proposed, together with the multidisciplinary supervisory team will ensure that students are equipped to become future leaders, and responsible innovators in the bioenergy sector.