The UK government pledges to achieve net zero emissions by 2050. Carbon capture and utilisation (CCU) in the cement and iron & steel sectors is considered a core measure toward this ambitious goal. An effective way of decarbonising the construction industry is to modify the Portland cement (PC) composition by reducing the clinker proportion. Replacing clinker with limestone (CaCO3, mainly calcite) proved to offset the CO2 emissions effectively while improving PC properties. Meanwhile, various alkaline solid wastes (ASW) have a significant potential of capturing CO2 whilst producing different CaCO3 polymorphs depending on the carbonation conditions. However, there is a lack of knowledge regarding the hydration characteristics of PC containing a range of CaCO3 polymorphs. In this proof-of-concept project, we will adopt steel slag (SS) as a representative ASW to validate the hypotheses that: (i) CaCO3 polymorphism can be regulated via controlling the carbonation conditions of SS and (ii) distinctively different CaCO3 polymorphs interact with PC differently. The main purpose of this project is to build a long-lasting partnership between researchers from the UK, China and Singapore, to collectively address the technical challenges of utilising ASW more efficiently and effectively as cement additives. The assembled project members from Cardiff University (UK), Nanjing Tech University (China) and Singapore Institute of Technology (Singapore) have complementary expertise in ASW characterisation and carbonation, cement science and structural engineering. The commonality of the team is our research interest in CCU in construction materials. Our intention is to share our knowledge and skills, advance the global understanding of ASW carbonation and utilisation in cement and concrete, and explore future research opportunities between academics from different countries.

Reason for the Project: The DIREKT project aims to instill best Information Literacy (IL) practices in higher education systems in the Russian Federation, Kazakhstan & China. The project is much needed in order to up-skill library and academic staff specifically their transferable, pedagogical and lifelong learning skills in the Information Literacy field thereby developing capacity and affecting all stakeholders including students. The project aims for improved, more relevant University services in the Information Literacy area leading to better awareness, modernization and improvements in teaching and learning. Concise Description: Creation with Librarians and Faculty, of curriculum-integrated IL programs (embedded in the three cycle system (bachelor/master/doctorate), quality assurance and recognition of qualifications for the development of lifelong learning in higher education and in Society at large and incorporating appropriate electronic media. Development of training programmes supported by 7 ECTS modules- a DIREKT Curriculum for Information Literacy which will be embedded in curricula in PC universities and with involvement of external stakeholders to ensure maximum transfer effect to Society at large.Impact envisaged: As Information Literacy is a vital transferable skill for lifelong learning that transcends all academic disciplines what is truly special and unique about this project is that the results will benefit a huge learner group- all University staff, students and librarians and the effects will be felt in RF, KZ and Chinese Society through university links with external stakeholders.

Continuing population and consumption growth are driving global food demand, with agricultural activity increasing to keep pace. Europe has a major agricultural waste problem, generating some 700 million tonnes of waste annually. There is an urgent need and huge opportunity to address the efficient use of agricultural wastes, co-products and by-products (AWCB) towards delivering sustainable value chains in the farming and processing sectors. As such, AgroCycle will convert low value agricultural waste into highly valuable products, achieving a 10% increase in waste recycling and valorisation by 2020. This will be achieved by developing a detailed and holistic understanding of the waste streams and piloting a key number of waste utilisation/valorisation pathways. It will bring technologies and systems from ~TRL4 to ~TRL7 within the 3 years of the project. A post-project commercialisation plan will bring commercially promising technologies/systems to TRL8 and TRL9, ensuring AgroCycle will have an enduring impact by achieving sustainable use of AWCB both inside and outside the agricultural sector, leading to the realisation of a Circular Economy. AgroCycle addresses wastes from several agricultural sectors: wine, olive oil, horticulture, fruit, grassland, swine, dairy and poultry. The AgroCycle consortium is a large (25) multi-national group (including China) comprising the necessary and relevant multi-actors (i.e. researchers; companies in the technical, manufacturing, advisory, retail sectors (Large and SMEs); lead users; end users; and trade/producer associations) for achieving the project’s ambitions goals. Farming’s unique regional (rural) location means that AgroCycle will help reduce the EU’s Innovation Divide and address the Regional Smart Specialisation Strategies for each partner country: impact will be Regional with National and International dimensions. The presence of three partners from China ensures international synergies and a global impact.

The last fifty years have seen spectacular progress in the ability to assemble materials with a precision of nanometers (a few atoms across). This nanofabrication ability is built upon the twin pillars of lithography and pattern transfer. A whole range of tools are used for pattern transfer. Lithography is a photographic process for the production of small structures in which structures are "drawn" in a thin radiation sensitive film. Then comes the pattern transfer step in which the shapes are transferred into a useful material, such as that of an active semiconductor device or a metal wire. Lithography is the key process used to make silicon integrated circuits, such as a microprocessor with eight billion working transistors, or a camera chip which is over two inches across. The manufacture of microprocessors is accomplished in large, dedicated factories which are limited to making one type of device. Also, normal lithography tools require the production of large, perfect and extremely expensive "negatives" so that it is only economical to use this technology to make huge numbers of identical devices. The applications of lithography are far broader than just making silicon chips, however. For example, large areas of small dots of material can be used to make cells grow in particular directions or to become certain cell types for use in regenerative medicine; The definition of an exquisitely precise diffraction grating on a laser allows it to produce the perfectly controlled wavelengths of light needed to make portable atomic clocks or to measure the tiny magnetic fields associated with the functioning of the brain; Lithography enables the direct manipulation of quantum states needed to refine the international standards of time and electrical current and may one day revolutionise computation; By controlling the size and shape of a material we can give it new properties, enabling the replacement of scarce strategic materials such as tellurium in the harvesting of waste thermal energy. This grant will enable the installation of an "electron-beam lithography" system in an advanced general-purpose fabrication laboratory. Electron beam lithography uses an electron beam rather than light to expose the resist and has the same advantages of resolution that an electron microscope has over a light microscope. This system will allow the production of the tiniest structures over large samples but does not need an expensive "negative" to be made. Instead, like a laser printer, the pattern to be written is defined in software, so that there is no cost associated with changing the shape if only one object of a particular shape is to be made. The electron beam lithography system is therefore perfect for making small things for scientific research or for making small numbers of a specialized device for a small company. The tool will be housed in a laboratory which allows the processing of the widest possible range of materials, from precious gem diamonds a few millimetres across to disks of exotic semiconductor the size of dinner plates. The tool will be used by about 200 people from all over the UK and the world. By running continuously the tool will be very inexpensive to use, allowing the power of leading-edge lithography to be used by anyone, from students to small businesses. The tool will be supported and operated by a large dedicated team of extremely experienced staff, so that the learning curve to applying the most advanced incarnation of the most powerful technology of the age will be reduced to a matter of a few weeks.

Our infrastructure is central to the economic prosperity of the nation and to the flourishing of a stable, yet dynamic, civil society. Its interconnected strands - the energy, transportation, water, sanitation and communication networks that provide access to services and markets and which underpin the securities of daily life - must be not only affordable and reliable but also resilient against threats such as technological uncertainty, environmental causes, economic and political change, and demographic and societal change unfolding in an increasingly uncertain world. FIBE2 CDT will lead a paradigm shift in the approach to infrastructure resilience through the creation of an inspirational doctoral training programme for talented cohorts from diverse academic and social backgrounds to conduct world-class, cutting-edge and industry-relevant research. Our goal is to develop the infrastructure professionals of the future, equipped with a versatile and cross-disciplinary skillset to meet the most complex emerging challenges, harness the full value of existing infrastructure and contribute effectively to better infrastructure decision-making in the UK. The programme's technical focus will exploit high-level interconnected research themes in advanced infrastructure materials, rethinking design & construction, digitised civil engineering, whole-life performance, built environment and global challenges, along high-level crosscutting themes in emerging technologies, performance to data to knowledge, research across scales, and risk and uncertainty. In FIBE2 CDT we offer a radical rethink to deliver innovation for the cross-disciplinary and interconnected challenges in resilient infrastructure. Our 1+3 MRes/PhD programme proposes a new approach to infrastructure research where students from different disciplines proactively forge new training and research collaborations. FIBE2 is inspired by the paradigm of a 3D 'T' shaped engineer embodying a combination of depth and breadth of knowledge, augmented by our new thinking around cross-disciplinary training and research. High level Infrastructure Engineering concepts will be interlinked and related to the detailed technical fundamentals that underpin them in bespoke core and elective modules. Cohort-based learning will bridge across the wider environmental, societal, economic, business and policy issues within the even broader context of ethics, responsible innovation and ED&I. These depth and breadth elements are interwoven and brought together through problem-based challenges using large-scale cross-disciplinary infrastructure projects. Individual student plans will be carefully crafted to harmonise the specificity of PhD research with the need for expansive understanding of threats and opportunities. The development of Resilient FIBE2 CDT students with strong personal, technical and professional resilience attributes is integral to the FIBE2 approach to training and research. The FIBE2 PhD projects will build upon Cambridge's internationally leading research, investment and funding in the diverse areas related to infrastructure and resilience. Our major strategic initiatives include >£60M funding from EPSRC and industry. Our engagements in UKCRIC, CDBB, Alan Turing and Henry Royce Institutes and our world class graduate training programmes provide an inspirational environment for the proposed CDT. The FIBE2 vision has been co-created with our 27 strategic industry partners from across all infrastructure sectors and nine international academic centre partners across the world, who have pledged over £12M. We will work together to deliver the FIBE2 CDT objectives and add new dimensions to our students' experience. The lasting impact of FIBE2 will be embodied in our students acting as role models to inspire future generations of infrastructure engineers and rising to lead the profession through all the technological and societal challenges facing UK infrastructure.