The manufacturing and processing of metals to form components is one of the largest industrial sectors and accounts for 46% of all manufactured value, with an economic value to the EEA of Euro 1.3 trillion annually. Material security concerns the access to raw materials to ensure military and economic sufficiency. We will face major future challenges as key elements will be increasingly in short supply with consequent price volatility ("the ticking time bomb"). Equally, many materials rely on strategic elements for which supply is not guaranteed, with rare earth elements being the prime example (central to the performance of magnesium alloys). Metals production consumes about 5% of global energy use and is responsible for an annual emission of over 2Gton of CO2, so efficiency in manufacture can produce significant reductions in environmental impact. The recent report "Material Security: Ensuring resource availability for the UK economy" from the TSB noted "the importance of material security has increased due to limited short-term availability of some raw materials, widespread large increases in raw material prices, oligopolistic industry structures and dependence on a limited number of sometimes politically unstable countries as sources of key materials". Furthermore, "The issue of sustainability has attained unprecedented prominence on both national and international agendas, occupying the minds of businesses and governments as never before... Resource efficiency has a key role to play in mitigating wider issues such as depletion of resources, environmental impact and materials security, and it also contributes significantly to the low-carbon economy." Addressing resource efficiency in metals production and use requires that new metal alloys be developed specifically to reduce reliance on strategic and scarce elements, for recycling and for disruptive manufacturing technologies that minimise waste. The size of the problem is too large to be undertaken by the traditional matrix experiment. Rather, a wide range of state-of-the-art modelling, experimental and processing skills needs to be brought together to target resource efficiency in metallic systems. In the DARE approach we use basic science to come to an understanding of the role of strategically important elements, to design new alloys with greater resource efficiency and to optimise the processing route for the new alloys to give supply chain compression. Unique to the DARE approach is to bring manufacturing into the centre of the alloy design paradigm. The combined themes will tackle key metal alloys, including ultra-high strength, low alloy and nanostructured steel (e.g. for a resource efficient approach to vehicle light weighting to give reduced automotive emissions); titanium alloys and titanium aluminides (e.g. for aerospace applications) and Mg alloys (e.g. in automotive and military applications, for example, cast gear box casings). The research team and their ten industrial partners will deliver actual materials and implementation into industry, moving the resource efficiency agenda from the sphere of policy into the real economy. We will support the growth of the high-value UK speciality metals manufacturing industry by developing and exploiting the DARE approach to the design of alloys that improve the resource efficiency and flexibility with regard to fluctuating material availability of the UK manufacturing economy, addressing the EPSRC grand challenges in transitioning to a low-carbon society. This will help existing UK world-leading industries to expand and manufacture for the future.

Metallic materials are used in an enormous range of applications, from everyday objects, such as aluminium drinks cans and copper wiring to highly-specialised, advanced applications such as nickel superalloy turbine blades in jet engines and stainless steel nuclear reactor pressure vessels. Despite advances in the understanding of metallic materials and their manufacture, significant challenges remain. Research in advanced metallic systems helps us to understand how the structure of a material and the way it is processed affects its properties and performance. This knowledge is essential for us to develop the materials needed to tackle current challenges in energy, transport and sustainability. We must learn how to use the earth's resources in a sustainable way, finding alternatives for rare but strategically important elements and increasing how much material we recycle and reuse. This will partly be achieved through developing manufacturing and production processes which use less energy and are less wasteful and through improving product designs or developing and improving the materials we use. In order to deliver these new materials and processes, industry requires a lot more specialists who have a thorough understanding of metallic materials science and engineering coupled with the professional and technical leadership skills to apply this expertise. The EPSRC Centre for Doctoral Training in Advanced Metallic Systems will increase the number of metallurgical specialists, currently in short supply, by training high level physical science and engineering graduates in fundamental materials science and engineering in preparation for doctoral level research on challenging metallic material and manufacturing problems. By working collaboratively with industry, while undertaking a comprehensive programme of professional skills training, our graduates will be equipped to be tomorrow's research leaders, knowledge workers and captains of industry.