The UK metal casting industry is a key player in the global market. It adds 2.6bn/year to the UK economy, employs directly around 30,000 people and produces 1.14 billion tons of metal castings, of which 37% is for direct export (Source: CMF, UK). It underpins the competitive position of every sector of UK manufacturing across automotive, aerospace, defence, energy and general engineering. However, its 500 companies are mainly SMEs, who are often not in a position to undertake the highest quality R&D necessary for them to remain competitive in global markets. The current EPSRC IMRC portfolio does not cover this important research area nor does it address this clear, compelling business need. We propose to establish IMRC-LiME, a 3-way centre of excellence for solidification research, to fill this distinctive and clear gap in the IMRC portfolio. IMRC-LiME will build on the strong metal casting centres already established at Brunel, Oxford and Birmingham Universities and their internationally leading capabilities and expertise to undertake both fundamental and applied solidification research in close collaborations with key industrial partners across the supply chain. It will support and provide opportunities for the UK metal casting industry and its customers to move up the value chain and to improve their business competitiveness. The main research theme of IMRC-LiME is liquid metal engineering, which is defined as the treatment of liquid metals by either chemical or physical means for the purpose of enhancing heterogeneous nucleation through manipulation of the chemical and physical nature of both endogenous (naturally occurring) and exogenous (externally added) nucleating particles prior to solidification processing. A prime aim of liquid metal engineering is to produce solidified metallic materials with fine and uniform microstructure, uniform composition, minimised casting defects and hence enhanced engineering performance. Our fundamental (platform) research theme will be centred on understanding the nucleation process and developing generic techniques for nucleation control; our user-led research theme will be focused on improving casting quality through liquid metal engineering prior to various casting processes. The initial focus will be mainly on light metals with expansion in the long term to a wide range of structural metals and alloys, to eventually include aluminium, magnesium, titanium, nickel, steel and copper. In the long-term IMRC-LiME will deliver: 1) A nucleation-centred solidification science, that represents a fundamental move away from the traditional growth-focused science of solidification. 2) A portfolio of innovative solidification processing technologies, that are capable of providing high performance metallic materials with little need for solid state deformation processing, representing a paradigm shift from the current solid state deformation based materials processing to a solidification centred materials engineering. 3) An optimised metallurgical industry, in which the demand for metallic materials can be met by an efficient circulation of existing metallic materials through innovative technologies for reuse, remanufacture, direct recycling and chemical conversion with limited additions of primary metal to sustain the circulation loop. This will lead to a substantial conservation of natural resources, a reduction of energy consumption and CO2 emissions while meeting the demand for metallic materials for economic growth and wealth creation.

Rare Earth Elements (REE) are used in many low carbon technologies, ranging from low energy lighting to permanent magnets in large wind turbines and hybrid cars. They are almost ubiquitous: in every smartphone and computer. Yet 97% of World supply comes from a few localities in China. Rare earth prices are volatile and subject to political control, and but substitute materials are difficult to design. The most problematic REEs to source are neodymium and the higher atomic number 'heavy' rare earths - a group dubbed the 'critical rare earths'. However, with many potential rare earth ore deposits in a wide variety of rocks, there is no underlying reason why rare earths should not be readily and relatively cheaply available. The challenge is to find and extract rare earths from the right locations in the most environmentally friendly, cost efficient manner to give a secure, reasonably priced, responsibly sourced supply. In this project, the UK's geological research experts in rare earth ore deposits team up with leaders in (a) geological fluid compositions and modelling, (b) using fundamental physics and chemistry of minerals to model processes from first principles and (c) materials engineering expertise in extractive metallurgy. This community brings expertise in carbonatites and alkaline rocks, some of the Earth's most extreme rock compositions, which comprise the majority of active exploration projects. The UK has a wealth of experience of study of economic deposits of rare earths (including the World's largest deposit at Bayan Obo in China) which will be harnessed. The team identify that a key issue is to understand the conditions that concentrate heavy rare earths but create deposits free from thorium and uranium that create radioactive tailings. Results so far from alkaline rocks and carbonatites are contradictory. A workshop will bring together the project team and partners, including a leading Canadian researcher on rare earth mobility, to debate the results and design experiments and modelling that can be done in the UK to solve this problem. Understanding, and then emulating how REE deposits form, may provide us with the best clues to extract REEs from their ores. One important route is to understand the clay-rich deposits in China which provide most of the World's heavy rare earths; they are simple to mine, not radioactive, and need little energy to process. The workshop will consider how these deposits form, how we can use our experimental and modelling expertise to understand them better and predict where companies should explore for them. The other main problem, restricting development of almost all rare earth projects, is the difficulty of efficient separation of rare earth ore minerals from each other and then extraction of the elements from those ores. A work shop on geometallurgy (linking geology through mining, processing, extractive metallurgy and behaviour in the environment) will be used to explore how geological knowledge can be used (a) to predict the processing and environmental characteristics of different types of ores and (b) to see if any new potential processing methods might be tried, taking advantage of fundamental mineralogical properties. The two workshops link geology to metallurgy, using one to inform the other. This project will form the basis for an international collaborative consortium bid to NERC. It will also catalyse a long-term UK multidisciplinary network linking rare earth researchers to users, and promote the profile of the UK in this world-wide important field. Before the team design the research programme, they will consult academic colleagues working on new applications of rare earths and rare earth recycling, plus exploration companies, users further along the up the supply chain and policy makers. This will ensure that the proposals developed have maximum impact on future supply chain security.