The future sustainable production of bulk and fine chemicals is an ever-increasing global challenge that requires a transformative scientific approach. We must develop new ways of efficiently exploiting valuable fossil-fuel resources and tools to exploit renewable resources such as CO2 and lignin. Catalytic methods, the heart of this CDT, are key to these transformations, offering the single most powerful and broadly applied technology for the reduction of energy demand, cost, environmental impact and toxicity. This CDT will drive forward a sustainable and resource-rich culture. This CDT in Critical Resource Catalysis (CRITICAT) combines the catalysis research collective of St. Andrews, Edinburgh, and Heriot-Watt Universities to create a new and unique opportunity in PhD training and research. CRITICAT will allow 80+ bright minds to be challenged in a comprehensive and state-of-the-art PhD training regime in the broad remit of catalytic science, transforming them into future scientific researchers, business leaders, entrepreneurs, and policy makers. These will be people who make a difference in a technologically-led society. Our critical mass in critical resource catalysis will accelerate training, discovery, understanding, and exploitation within catalytic chemistry. We will focus our efforts on the future of catalysis, driving new advances for environmentally sustainable economic growth and underpinning current growth in the UK chemicals sector. The economic impact in this area is huge: in 2010, an EPSRC/RSC jointly commissioned independent report showed that the UK's "upstream" chemicals industry and "downstream" chemistry-using sector contributed a combined total of £258 billion in added value to the economy in 2007, equivalent to 21% of UK GDP, and supported over 6 million UK jobs. Sustained investment in PhD training within this area will provide the highest quality employees for this sector. The CRITICAT PhD students will be exposed to a unique training and research environment. Extensive taught courses (delivered by CRITICAT PIs and industrial collaborators) will offer fundamental insight into homogeneous, heterogeneous, industrial and biocatalysis coupled with engineering concepts and essential techniques to showcase cutting-edge catalysis. The CRITICAT partners will develop these core courses into a foundational textbook for graduate training across catalysis using critical resources as its cornerstone that will serve as a legacy for this programme. We will expand our pedagogical innovation to all PhD graduate students at our three partner universities, providing region-wide enhanced academic provision. Continuous growth and peer-to-peer learning throughout their research efforts will create graduates who are keen to continue learning. They will be equipped with business, management, entrepreneurial and communication skills synergistic with core science knowledge and research undertakings. In this way, we will ensure that our CRITICAT students will be able to innovate, think critically, and adapt to change in any technological career. We will prepare the next generation of scientists, managers and innovators for key roles in our future society. To support this broad developmental approach, industry and business leaders will contribute widely to CRITICAT. Industries will (i) provide scientific ideas and objectives, (ii) deliver new competencies through targeted courses ranging from entrepreneurship to intellectual property rights and (iii) provide laboratory placements to consolidate learning and exploit any scientific advances. Furthermore, our extensive collaboration with leading international academic institutions will engender PhD student mobility, expand impact and allow experiential learning. We will build on our existing public engagement frameworks to enable our students to deliver their research, impact and scientific understanding to a wide audience, exciting others and driving new scientific policy.

We propose to build the EPSRC Centre for Doctoral Training in Sensor Technologies for a Healthy and Sustainable Future (Sensor CDT) on the foundations we have established with our current CDT (EPSRC CDT for Sensor Technologies and Applications, see http://cdt.sensors.cam.ac.uk). The bid falls squarely into EPSRC's strategic priority theme of New Science and Technology for Sensing, Imaging and Analysis. The sensor market already contributes an annual £6bn in exports to the UK economy, underpinning 73000 jobs and markets estimated at £120bn (source: KTN UK). Major growth is expected in this sector but at the same time there is a growing problem in recruiting suitably qualified candidates with the necessary breadth of skills and leadership qualities to address identified needs from UK industry and to drive sustainable innovation. We have created an integrated programme for high quality research students that treats sensing as an academic discipline in its own right and provides comprehensive training in sensor technologies all the way from the fundamental science of sensing, the networking and interpretation of sensory data, to end user application. In the new, evolved CDT, we will provide training for our CDT students on themes that are of direct relevance to a sustainable and healthy future society, whilst retaining a focus that delivers value to the UK economy and academia. The 4-year programme is strongly cross disciplinary and focuses on sustainable development goals and emphasises training in Responsible Innovation. One example of the latter is our objective to 'democratise sensor technologies': Our students will learn how to engage with the public during research, how to play a valuable part in public debate, and how to innovate technology that benefits society. Technical aspects will be taught in a bespoke training programme for the course, that includes lectures, practicals, lab rotations, industry secondments, and skills training on key underpinning technologies. To support this effort, we have created dedicated, state-of-the-art infrastructure for the CDT that includes laboratory, office, teaching, and social spaces, and we connect to the world leading infrastructure available in the participating departments and partner industries. The programme is designed to create strong identities both within and across CDT cohorts (horizontal and vertical integration) to maximise opportunities for peer-to-peer learning and leadership training through activities such as our unique sensor team challenges and the monthly Sensor Cafés, attended by representatives from academia, industry, government agencies, and the public. We will create a diverse and inclusive atmosphere where students feel confident and empowered to offer different opinions and experiences and which maximises creativity and innovation. We have attracted substantial interest and support (>£2.5M) from established industrial partners, but our new programme emphasises engagement also with UK start-ups and SMEs, who are particularly vulnerable in the current economic climate and who have expressed a need for researchers with the breadth and depth of skills the CDT provides (see letters of support). We recruit outstanding, prizewinning students from a diverse range of disciplines and the training programme connects more than 90 PIs across 15 departments and 40 industrial partners working together to address future societal needs with novel sensor technologies. Technology developers will benefit through connection with experts in middleware (e.g. sensor distribution and networking, data processing) and applications experts (e.g. life scientists, atmospheric scientists, etc.) and vice versa. This integrative character of the CDT will inspire innovations that transform capability in many disciplines of science and industries.

This project will investigate if crowdsourcing can be used to aggregate the content of disparate, open-data sources across the internet to determine which patents underpin commercial products, and organise and present these according to technical criteria in a visual "gallery" form appropriate for engineering design. Patents are frequently used to quantify levels of innovation associated with specific regions or companies. However despite the development of sophisticated data mining tools to support the analysis of over 50 million online patent records, little is known about which patents are actually "commercialized" and how they are embodied in commercial products. Because of this "patent informatics" has been inherently limited to the study of the records, rather than the use, of Intellectual Property (IP). This information gap inevitably reduces the accuracy of academic and commercial analysis that use patent data for applications such as innovation research, R&D fore-sighting, and IP portfolio valuations. Furthermore, the presentation of existing data maps is not in a form that is useful for engineering designers when conceptualising and embodying products: it is predominantly text-based (and often deliberately obfuscated) when more visual presentation with exemplars and appropriate technical taxonomic terms would greatly enhance utility when undertaking engineering design development. Crowdsourcing utilises large networks of open people to compete discrete tasks. Virtual tools are used to co-ordinate the distribution, payment and co-ordination of results, resulting in a labour market that is open 24/7 and a diverse workforce available to perform tasks quickly and cheaply. The distributed network of human workers provide on-line, "black-box", reasoning capabilities that could far exceed the capabilities of current AI technologies (i.e. genetic algorithms, neural-nets, case-based reasoning) in terms of flexibility and scope. This project proposes that crowdsourcing can be utilised to access open data sources such as user manuals, product labelling, court proceedings and company web pages to understand which patents are actively used in current products and how they have been embodied. With a more accurate representation of innovation commercialisation, technical metadata (labelling), and utilisation, we envisage patent searches not as a stage-gate check but as a revitalised source of design inspiration. Indeed, if crowdsourcing proves a cheap, scalable way of collating this information and applying appropriate taxonomic and visual engineering information, it could fundamentally alter the early phases of engineering design. To this end, the project will result in a visualization tool that can be used to both guide and inspire design conceptualisation and embodiment.

The Scottish Doctoral Training Centre in Condensed Matter Physics, known as the CM-DTC, is an EPSRC-funded Centre for Doctoral Training (CDT) addressing the broad field of Condensed Matter Physics (CMP). CMP is a core discipline that underpins many other areas of science, and is one of the Priority Areas for this CDT call. Renewal funding for the CM-DTC will allow five more annual cohorts of PhD students to be recruited, trained and released onto the market. They will be highly educated professionals with a knowledge of the field, in depth and in breadth, that will equip them for future leadership in a variety of academic and industrial careers. Condensed Matter Physics research impacts on many other fields of science including engineering, biophysics, photonics, chemistry, and materials science. It is a significant engine for innovation and drives new technologies. Recent examples include the use of liquid crystals for displays including flat-screen and 3D television, and the use of solid-state or polymeric LEDs for power-saving high-illumination lighting systems. Future examples may involve harnessing the potential of graphene (the world's thinnest and strongest sheet-like material), or the creation of exotic low-temperature materials whose properties may enable the design of radically new types of (quantum) computer with which to solve some of the hardest problems of mathematics. The UK's continued ability to deliver transformative technologies of this character requires highly trained CMP researchers such as those the Centre will produce. The proposed training approach is built on a strong framework of taught lecture courses, with core components and a wide choice of electives. This spans the first two years so that PhD research begins alongside the coursework from the outset. It is complemented by hands-on training in areas such as computer-intensive physics and instrument building (including workshop skills and 3D printing). Some lecture courses are delivered in residential schools but most are videoconferenced live, using the well-established infrastructure of SUPA (the Scottish Universities Physics Alliance). Students meet face to face frequently, often for more than one day, at cohort-building events that emphasise teamwork in science, outreach, transferable skills and careers training. National demand for our graduates is demonstrated by the large number of companies and organisations who have chosen to be formally affiliated with our CDT as Industrial Associates. The range of sectors spanned by these Associates is notable. Some, such as e2v and Oxford Instruments, are scientific consultancies and manufacturers of scientific equipment, whom one would expect to be among our core stakeholders. Less obviously, the list also represents scientific publishers, software houses, companies small and large from the energy sector, large multinationals such as Solvay-Rhodia and Siemens, and finance and patent law firms. This demonstrates a key attraction of our graduates: their high levels of core skills, and a hands-on approach to problem solving. These impart a discipline-hopping ability which more focussed training for specific sectors can complement, but not replace. This breadth is prized by employers in a fast-changing environment where years of vocational training can sometimes be undermined very rapidly by unexpected innovation in an apparently unrelated sector. As the UK builds its technological future by funding new CDTs across a range of priority areas, it is vital to include some that focus on core discipline skills, specifically Condensed Matter Physics, rather than the interdisciplinary or semi-vocational training that features in many other CDTs. As well as complementing those important activities today, our highly trained PhD graduates will be equipped to lay the foundations for the research fields (and perhaps some of the industrial sectors) of tomorrow.