• Canada

This proposal will bring together sediment remediation engineers, ecotoxicologists and hydrogeochemists at an early stage of their career. They will gather for a one week launch event at Newcastle University to learn about each others conceptual understanding of sediment pollution issues and to discuss feasible solutions to these. The launch activities will include discipline hopping in oral presentations, one-on-one pairing of researchers from different disciplines explaining their research efforts to each other, practical training in the calibration and use of pollutant fate modelling tools, visits to local sites with sediment pollution, group discussion of possible solutions to international case studies of sediment pollution, and the conceptual design of better interdisciplinary models of sediment pollution and its effect on sediment-dwelling and aquatic organisms.During the launch event the researchers will submit proposals for people exchange activities with the partner institutions. Such individual visits will allow the researchers to deepen the mutual understanding of work at other institutions and in other disciplines. It is expected that future international and interdisciplinary research collaborations will emerge from such opportunities, and that the established personal contacts will continue to pay dividends throughout the career of the young participants.

Canada

This project will quantify the effect of surface generated melt-water fluctuations on ice motion at the margin of the Greenland Ice Sheet (GrIS). More specifically, it will provide data that will enable ice-sheet modellers to improve their predictions of the future contribution of the GrIS to sea level rise in response to a warming world. To achieve this aim requires a dedicated field campaign to the GrIS to investigate seasonal ice flow dynamics and runoff processes along flow parallel transects extending from the ice sheet margin to the equilibrium line altitude (ELA) at both tidewater and land-terminating glaciers. The greatest store of fresh water in the northern hemisphere - equivalent to 7m of eustatic sea level rise - is held within the Greenland Ice Sheet (GrIS), and yet its present and future contribution to sea level is poorly constrained (IPCC, 2007). Recent observations suggest that mass loss near the margin of the GrIS is accelerating through a combination of increased surface melting (e.g. Steffen et al, 2004) and dynamic thinning (e.g. Rignot and Kanagaratnam, 2006). However, the key processes controlling dynamic thinning have yet to be identified (Alley et al, 2005), and in consequence, are not incorporated in the ice-sheet models which form the basis of the IPCC sea level projections. This in part reflects the fact that the satellite data that has revealed the widespread speed-up of glaciers cannot be acquired at the temporal resolution needed to resolve the causal mechanisms. Our present understanding of GrIS mass balance is especially complicated by uncertainties in the sensitivity of ice-marginal dynamics to changes in melt-water induced lubrication resulting from penetration of supraglacial melt-waters to the glacier bed (Zwally et al, 2002). Recent observations on the GrIS Shepherd et al, in review) reveal, over a five day period in July, a strong and direct coupling between surface hydrology and dynamics where diurnal fluctuations in velocity of >100% occur and where maximum daily velocities scale with temperature. Such observations confirm the need to acquire hydrological and dynamic data at high temporal (sub-hourly) and spatial resolution throughout the year to parameterise the coupling between ice melting and flow. This project will collect data at the necessary resolution to quantify the relationship between melt-water production and ice sheet dynamics thereby enabling ice-sheet modellers to improve predictions of the GrIS's response to climate change. We will conduct ground based experiments along two flow-parallel transects at the western margin of the GrIS in adjacent land and marine terminating drainage basins to address the following objectives: 1. Is there a temporal and spatial pattern to any hydrology-dynamic link associated with the seasonal evolution of the supraglacial drainage system (including supraglacial lakes)? 2. Over what area does surface generated meltwater penetrate to the base of the ice sheet? 3. Is there a relationship between the volume of meltwater input at the glacier surface and the magnitude of the dynamic response? 4. Do tidewater and land-terminating glaciers behave differently during the course of a melt-season? Field campaigns will be undertaken during 2008 and 2009 to determine: 1) The rate, extent and duration of melt. 2) The temporal and spatial variations in water volumes stored in and released from supraglacial lakes and delivered to freely draining moulins. 3) The seasonal, diurnal and hourly variations in ice dynamics. 4) The variations in proglacial discharge and water chemistry (at Russell Glacier). As a result of our work, it will be possible to determine whether ice dynamics at the margin of the GrIS is significantly affected by lubrication of the glacier bed following the drainage of surface derived meltwaters. Our results will be delivered to ice sheet modellers to help them constrain predictions for the future of the GrIS

This research will create a truly innovative, international research network that will stretch far and wide in the area of "Cultures of Creativity and Innovation in Design". The international research network coordinating body comprises Professors Paul Rodgers and Paul Jones from Northumbria University, Professor Amaresh Chakrabarti, a world-leading researcher in Design Creativity, from the Centre for Product Design and Manufacturing at the Indian Institute of Science, Bangalore and Professor Lorenzo Imbesi, an internationally-acclaimed researcher in Design Culture, from the School of Industrial Design at Carleton University, Canada. The importance of creativity in the cultural, creative and other industries and the significant contributions that creativity adds to a nation's overall GDP and the subsequent health and wellbeing of its people cannot be overstated. In Europe, the value of the cultural and creative industries is estimated at well over 700 billion Euros each year, twice that of Europe's car manufacturing industry. The value of creativity and innovation, to any nation, is therefore huge. Creativity and innovation adds real value, which enables a number of benefits such as economic growth and social wellbeing. In many societies creativity epitomises success, excitement and value. Whether driven by individuals, companies, enterprises or regions creativity and innovation establishes immediate empathy, and conveys an image of dynamism. Creativity is thus a positive word in societies constantly aspiring to innovation and progress. In short, creativity in all of its manifestations enriches society. This network seeks to gain an understanding of this dynamic ecology that creativity and innovation bring to society. Creativity is a vital ingredient in the production of products, services and systems, both in the cultural industries and across the economy as a whole. Yet despite its importance and the ubiquitous use of creativity as a term there are issues regarding its definitional clarity. A better understanding and articulation of creativity as a concept and a process would support enhanced future innovation. Socio-cultural approaches to creativity explain that creative ideas or products do not happen inside people's heads, but in the interaction between a person's thoughts and a socio-cultural context. It is acknowledged that creativity cannot be taught, but that it can be cultivated and this has significant implications for a nation's design and innovation culture. It is known that creativity flourishes in congenial environments and in creative climates. This research will examine how creativity is valued, exploited, and facilitated across different national and cultural settings as all can have a major impact on a nation's creative potential. The key aim of this network is to investigate attitudes about creativity and how it is best cultivated and exploited across three different geographical locations (UK, India, and Canada), different environments, and cultures from both an individual designer's perspective and design groups' perspectives. The network seeks to investigate cultures of creativity and innovation in design and question its nature. For instance, can creativity be adequately conceptualised in a design context? What role do cultural organisations and national bodies play in harnessing creativity? Where do the "edges" lie between creativity and innovation? Do richer environments and approaches for facilitating creativity exist? What design skills, knowledge, and expertise are required for creativity? Moreover, what are the key drivers that motivate the creativity and innovation of designers and other stakeholders? Are they economical, cultural, social, or political? This research network will host 3 workshops, each one facilitating inquiry amongst invited design practitioners, researchers, educators and other stakeholders involved in design practice.

The EPSRC Centre for Doctoral Training in Renewable Energy Northeast Universities (ReNU) is driven by industry and market needs, which indicate unprecedented growth in renewable and distributed energy to 2050. This growth is underpinned by global demand for electricity which will outstrip growth in demand for other sources by more than two to one (The drivers of global energy demand growth to 2050, 2016, McKinsey). A significant part of this demand will arise from vast numbers of distributed, but interconnected devices (estimated to reach 40 billion by 2024) serving sectors such as healthcare (for ageing populations) and personal transport (for reduced carbon dioxide emission). The distinctive remit of ReNU therefore is to focus on materials innovations for small-to-medium scale energy conversion and storage technologies that are sustainable and highly scalable. ReNU will be delivered by Northumbria, Newcastle and Durham Universities, whose world-leading expertise and excellent links with industry in this area have been recognised by the recent award of the North East Centre for Energy Materials (NECEM, award number: EP/R021503/1). This research-focused programme will be highly complementary to ReNU which is a training-focused programme. A key strength of the ReNU consortium is the breadth of expertise across the energy sector, including: thin film and new materials; direct solar energy conversion; turbines for wind, wave and tidal energy; piezoelectric and thermoelectric devices; water splitting; CO2 valorisation; batteries and fuel cells. Working closely with a balanced portfolio of 36 partners that includes multinational companies, small and medium size enterprises and local Government organisations, the ReNU team has designed a compelling doctoral training programme which aims to engender entrepreneurial skills which will drive UK regional and national productivity in the area of Clean Growth, one of four Grand Challenges identified in the UK Government's recent Industrial Strategy. The same group of partners will also provide significant input to the ReNU in the form of industrial supervision, training for doctoral candidates and supervisors, and access to facilities and equipment. Success in renewable energy and sustainable distributed energy fundamentally requires a whole systems approach as well as understanding of political, social and technical contexts. ReNU's doctoral training is thus naturally suited to a cohort approach in which cross-fertilisation of knowledge and ideas is necessary and embedded. The training programme also aims to address broader challenges facing wider society including unconscious bias training and outreach to address diversity issues in science, technology, engineering and mathematics subjects and industries. Furthermore, external professional accreditation will be sought for ReNU from the Institute of Physics, Royal Society of Chemistry and Institute of Engineering Technology, thus providing a starting point from which doctoral graduates will work towards "Chartered" status. The combination of an industry-driven doctoral training programme to meet identifiable market needs, strong industrial commitment through the provision of training, facilities and supervision, an established platform of research excellence in energy materials between the institutions and unique training opportunities that include internationalisation and professional accreditation, creates a transformative programme to drive forward UK innovation in renewable and sustainable distributed energy.