This project is a feasibility study aimed at establishing the viability of a new class of material for hydrogen storage namely pillared nanographites. One of the more challenging problems in energy research is to find a compact, safe and lightweight alternative to petroleum that has similar energy densities. There are a large number of different potential solutions to this problem, but the use of hydrogen has interesting possibilities in that it promises a clean, efficient and quiet form of energy storage. We believe that we have identified a new class of materials, pillared nanographites, that will be able to satisfy this need and are also cheap and environmentally friendly (recyclable). The hydrogen absorption properties of these materials are highly tuneable via control of the interlayer spacing, the concentration and type of intercalant, the surface charge, and nano-scale texture. Furthermore, our compounds are cheap, recyclable and environmentally friendly (they do not contain toxic heavy metals). We would therefore like to request funds for an exploratory study that will establish the feasibility or otherwise of these materials. Although it is quite speculative in nature, this project has strong support from Toyota Motors.

This collaboration will open an adventurous new application for quantum sensing with wide reaching applications in the environmental sciences. We are aiming for improving the reference frame used by researchers in climate science to allow higher precision climate data to be collected, better models to be made and improved evidence for political decisions to be generated. As stated by the UN: "The Global Geodetic Reference Frame (GGRF) is the foundation for evidence-based policies and decisions, it underpins the collection and management of nationally integrated geospatial information and is used to monitor our dynamic Earth. Thus, the GGRF has direct societal relevance." This is the pivotal element we are targeting in this project. In more detail, we are using the latest developments in quantum sensors and perform research into making them sufficiently robust to achieve world-record precision inside the UK Space Geodesy Facility in Herstmonceux. In parallel we will research into the tools to use the continuous stream of precise gravity data from the quantum sensor to better understand the tide models and other effects influencing the measurements defining our geodetic reference frames.

This project is a feasibility study aimed at establishing the viability of a new class of material for hydrogen storage namely pillared nanographites. One of the more challenging problems in energy research is to find a compact, safe and lightweight alternative to petroleum that has similar energy densities. There are a large number of different potential solutions to this problem, but the use of hydrogen has interesting possibilities in that it promises a clean, efficient and quiet form of energy storage. We believe that we have identified a new class of materials, pillared nanographites, that will be able to satisfy this need and are also cheap and environmentally friendly (recyclable). The hydrogen absorption properties of these materials are highly tuneable via control of the interlayer spacing, the concentration and type of intercalant, the surface charge, and nano-scale texture. Furthermore, our compounds are cheap, recyclable and environmentally friendly (they do not contain toxic heavy metals). We would therefore like to request funds for an exploratory study that will establish the feasibility or otherwise of these materials. Although it is quite speculative in nature, this project has strong support from Toyota Motors.

Since the beginning of humanity our societies have been based on commerce, i.e. we make things and we sell them to other people. Relatively simple beginnings led to the Industrial Revolution and now to the technological age. Over-generalising, the Far East are currently the masters of mass manufacture and the West are (or wish to be) the masters of advanced manufacture - the production of high-value goods, often involving a significant degree of innovation. To be able to manufacture goods in a cost-effective, environmentally-sustainable manner, quality control procedures are required. And quality control in turn requires an appropriate measurement infrastructure to be in place. It is a sub-set of this measurement infrastructure that is the subject of this fellowship. The UK government has been investing heavily in advanced manufacturing. In the academic arena, there are the sixteen EPSRC Centres of Innovative Manufacturing. To ease the pain of transferring academic research to the manufacturing sector, there are the seven High-Value Manufacturing Catapults (the Manufacturing Technology Centre being the main one of note here). For industry, there are a number of funding initiatives and tax breaks. To support this burgeoning UK advanced manufacturing infrastructure, there are a small number of academic centres for metrology - those based at Huddersfield and Bath are the main players. And, at the top of the measurement tree, there is the world-class National Physical Laboratory - a centre of excellence in metrology. But, there are still some gaps in the manufacturing metrology research jigsaw, and the aim of this fellowship is to plug those gaps. Coordinate metrology has been used for decades in the manufacturing industry as the most dominant form of process control, usually employing tactile coordinate measuring machines (CMMs). However, due to the slow speed of tactile systems and the fact that they can only take a limited amount of points, optical CMMs are starting to flourish. On the smaller scale, there are many optical surface measuring devices that tend to be used off-line in industry. When making small, high-precision, complex components, with difficult to access geometries, it is a combination of the surface measurement systems and the CMMs that is required. This requirement is one of the main aims of the fellowship - to develop a suite of fast, high-accuracy, non-contact measurement systems, which can be employed in industry. These principles will also be applied to the field of additive manufacturing - a new paradigm in manufacturing which is seeing significant government support and, in some cases, media hype. As with high-precision components, a coordinate metrology infrastructure for additive manufacturing is required, in many cases in-line to allow direct feedback to the manufacturing process. This is the second field of metrology that the fellowship will address. The outputs of the fellowship will be in the form of academic publications; new measurement instruments, along with new ways to use existing instruments; methods to allow manufacturers to verify the performance of their instruments; and the necessary pre-normative work that will lead to specification standards in the two fields (currently lacking). The academic world will benefit from the fundamental nature of elements of the research, and the industrial manufacturing world will benefit from the techniques developed and routes to standardisation. But, ultimately, it will be the UK citizens that will reap the greatest benefit in terms of new and enhanced products, and the wealth creation potential from precision and additive manufacturing.

The UK Government recently set targets for "net zero emissions" and "zero waste" as well as a 10 Point Plan for a Green Industrial Revolution. Even so, the UK currently sources, processes and deploys advanced materials based on unsustainable practices, including the use of fossil fuels and scarce, geologically hindered raw materials. This contributes to over 30% of the UK CO2 emissions, especially considering the import of raw precursors and materials. Our vision is to build our most important functional materials from bio-based resources which are locally available. These materials will lower CO2 emissions, helping the UK to reach the targeted zero emissions by 2050 while boosting high-performance, locally available technologies and creating new industries. They will form the cornerstone for a modern technology-dependent economy. This programme grant brings together the best UK academics and key industrial partners involved in the development of a new supply chain for sustainable materials and applications. We will accelerate novel pathways to manufacture advanced materials out of available UK bioresources while boosting their performance working with stakeholders in key industrial sectors (chemical industry, advanced materials, energy, waste, agriculture, forestry, etc). The combined food, forestry and agricultural waste in the UK amounts to approx.26.5m tonnes each year. There is no valuable economic chain in the UK to allow waste valorisation towards high value-added materials. Yet, by mass, functional materials provide the most viable route for waste utilisation, preferable over waste-to-energy. This Programme Grant will thus enhance the UK's capability in the critical area of affordable and sustainable advanced materials for a zero carbon UK economy, providing multidisciplinary training for the next generation of researchers, and support for a nascent next generation of an advanced materials industry