There are major challenges inherent in meeting the goals of the UK national energy policy, including, climate change mitigation and adaption, security of supply, asset renewal, supply infrastructure etc. Additionally, there is a recognized shortage of high quality scientists and engineers with energy-related training to tackle these challenges, and to support the UK's future research and development and innovation performance as evidenced by several recent reports;Doosan Babcock (Energy Brief, Issue 3, June 2007, Doosan Babcock); UK Energy Institute (conducted by Deloitte/Norman Broadbent, 'Skills Needs in the Energy Industry' 2008); The Institution of Engineering and Technology, (evidence to the House of Commons, Select Committee on Innovation, Universities, Science and Skills Fifth Report (19th June 2008); The Energy Research Partnership (Investigation into High-level Skills Shortages in the Energy Sector, March 2007). Here we present a proposal to host a Doctoral Training Centre (DTC) focusing on the development of technologies for a low carbon future, providing a challenging, exciting and inspiring research environment for the development of tomorrow's research leaders. This DTC will bring together a cohort of postgraduate research students and their supervisors to develop innovative technologies for a low carbon future based around the key interlinking themes: [1] Low Carbon Enabling Technologies; [2] Transport & Energy; [3] Carbon Storage, underpinned by [4] Climate Change & Energy Systems Research. Thereby each student will develop high level expertise in a particular topic but with excitement of working in a multidisciplinary environment. The DTC will be integrated within a campus wide Interdisciplinary Institute which coordinates energy research to tackle the 'Grand Challenge' of developing technologies for a low carbon future, our DTC students therefore working in a transformational research environment. The DTC will be housed in a NEW 14.8M Energy Research Building and administered by the established (2005) cross campus Earth, Energy & Environment (EEE) University Interdisciplinary Institute

The Transforming the Foundation Industries Challenge has set out the background of the six foundation industries; cement, ceramics, chemicals, glass, metals and paper, which produce 28 Mt pa (75% of all materials in our economy) with a value of £52Bn but also create 10% of UK CO2 emissions. These materials industries are the root of all supply chains providing fundamental products into the industrial sector, often in vertically-integrated fashion. They have a number of common factors: they are water, resource and energy-intensive, often needing high temperature processing; they share processes such as grinding, heating and cooling; they produce high-volume, often pernicious waste streams, including heat; and they have low profit margins, making them vulnerable to energy cost changes and to foreign competition. Our Vision is to build a proactive, multidisciplinary research and practice driven Research and Innovation Hub that optimises the flows of all resources within and between the FIs. The Hub will work with communities where the industries are located to assist the UK in achieving its Net Zero 2050 targets, and transform these industries into modern manufactories which are non-polluting, resource efficient and attractive places to be employed. TransFIRe is a consortium of 20 investigators from 12 institutions, 49 companies and 14 NGO and government organisations related to the sectors, with expertise across the FIs as well as energy mapping, life cycle and sustainability, industrial symbiosis, computer science, AI and digital manufacturing, management, social science and technology transfer. TransFIRe will initially focus on three major challenges: 1 Transferring best practice - applying "Gentani": Across the FIs there are many processes that are similar, e.g. comminution, granulation, drying, cooling, heat exchange, materials transportation and handling. Using the philosophy Gentani (minimum resource needed to carry out a process) this research would benchmark and identify best practices considering resource efficiencies (energy, water etc.) and environmental impacts (dust, emissions etc.) across sectors and share information horizontally. 2 Where there's muck there's brass - creating new materials and process opportunities. Key to the transformation of our Foundation Industries will be development of smart, new materials and processes that enable cheaper, lower-energy and lower-carbon products. Through supporting a combination of fundamental research and focused technology development, the Hub will directly address these needs. For example, all sectors have material waste streams that could be used as raw materials for other sectors in the industrial landscape with little or no further processing. There is great potential to add more value by "upcycling" waste by further processes to develop new materials and alternative by-products from innovative processing technologies with less environmental impact. This requires novel industrial symbioses and relationships, sustainable and circular business models and governance arrangements. 3 Working with communities - co-development of new business and social enterprises. Large volumes of warm air and water are produced across the sectors, providing opportunities for low grade energy capture. Collaboratively with communities around FIs, we will identify the potential for co-located initiatives (district heating, market gardening etc.). This research will highlight issues of equality, diversity and inclusiveness, investigating the potential from societal, environmental, technical, business and governance perspectives. Added value to the project comes from the £3.5 M in-kind support of materials and equipment and use of manufacturing sites for real-life testing as well as a number of linked and aligned PhDs/EngDs from HEIs and partners This in-kind support will offer even greater return on investment and strongly embed the findings and operationalise them within the sector.

The research will investigate the nature of the loading patterns imparted onto tidal stream turbines when positioned and operated within an array and develop operational procedures to mitigate the impacts of these extreme loading patterns. Exposure to open sea wave climates with high wave-current interactions will influence the power generating, structural integrity, product durability and maintenance requirements of the technologies deployed. The research will undertake both experimental and numerical analyses in a manner that will make the results and findings transferable to real-life implementations. This will inform developers of the peak and fluctuating loads that devices are exposed to in a commercial array environment and will also identify and test mitigating actions to be implemented in order to ensure the robustness and sustainability of the array. The dynamic, cyclic loadings on a tidal stream turbine have been shown to depend on the current profile and wave characteristics which can increase the severity of these loads. This must be considered in the design of the turbine. A turbine in an array will be subjected to more complex flows due to its position in the array, which will result in more diverse loading patterns, which must be fully understood by the turbine designers and operators. The project will therefore evaluate and measure the loading and performance of different configurations of tidal stream turbine arrays using numerical modelling and model scaled experiments. The numerical modelling will use fluid and structural modelling. An existing and proven, instrumented, laboratory scale turbine design will used for the tests. Initial work on a three turbine array will be undertaken to create models of a full-scale turbine array to determine the power output, loading patterns and accurate life-fatigue analysis based on realistic site deployment conditions. This information will be formulated to provide a basis for the industry to evaluate anticipated performance, monitoring needs, operational best practice and maintenance regimes in order to deliver the lowest cost of energy from tidal arrays

Artificial intelligence (AI) is undergoing an era of explosive growth. With increasingly capable AI agents such as chatGPT, AlphaFold, Gato and DALL-E capturing the public imagination, the potential impact of AI on modern society is becoming ever clearer for all to see. APRIL is a project that seeks to bring the benefits of AI to the electronics industry of the UK. Specifically, we aspire developing AI tools for cutting development times for everything from new, fundamental materials for electronic devices to complicated microchip designs and system architectures, leading to faster, cheaper, greener and overall, more power-efficient electronics. Imagine a future where extremely complex and intricate material structures, far more complex than what a human could design alone, are optimised by powerful algorithms (such as an AlphaFold for semiconductor materials). Or consider intelligent machines with domain-specialist knowledge (think of a Gato-like system trained on exactly the right milieu of skills) experimenting day and night with manufacturing techniques to build the perfect electronic components. Or yet what if we had algorithms trained to design circuits by interacting with an engineer in natural language (like a chatGPT with specialist knowledge)? Similar comments could be made about systems that would take care of the most tedious bits of testing and verifying increasingly complex systems such as mobile phone chipsets or aircraft avionics software, or indeed for modelling and simulating electronics (both potentially achievable by using semi-automated AI coders such as Google's "PaLM" model). This is precisely the cocktail of technologies that APRIL seeks to develop. In this future, AI - with its capabilities of finding relevant information, performing simple tasks when instructed to do so and its incredible speed - would operate under the supervision of experienced engineers for assisting them in creating electronics suited to an ever-increasing palette of requirements, from low-power systems to chips manufactured to be recyclable to ultra-secure systems for handling the most sensitive and private data. To achieve this, APRIL brings together a large consortium of universities, industry and government bodies, working together to develop: i) the new technologies of the future, ii) the tools that will make these technologies a reality and very importantly, iii) the people with the necessary skills (for building as well as using such new tools) to ensure that the UK remains a capable and technologically advanced player in the global electronics industry.

Fusion Forest is a radically novel and interdisciplinary approach to design our future treescapes. We face a challenging scenario, where tree cover needs to be increased - the UK government has set out a 25-year programme to plant 180,000 hectares of trees by 2042 and to increase the woodland cover to 12% by 2060 - whilst there is an alarming increase in tree epidemics. These outbreaks, favoured by increased disease portability, chemical resistances and climate change, compromise the future of our woodlands, producing a dramatic loss of biodiversity and resources. We propose a proactive strategy where new plantations are designed from the onset to halt and suppress diseases using their natural immunity. Fusion Forest achieves so by cutting through discipline boundaries and establishing synergies among the latest discoveries and techniques in tree immunity, ecological modelling and fluids modelling. Fusion Forest seeks to understand how to stimulate priming of defence in trees by using careful combinations of species and lowering the disease pressure. In parallel, the project incorporates the often overlooked spatial component of forest canopies and uses forest heterogeneity to our advantage, creating physical barriers that complement and enhance the ecological ones. To do so, we design a new interdisciplinary modelling framework - named ForestFlow - that brings together forest growth models and computational fluid dynamics. The understanding gained from the ecophysical model, complemented by field and laboratory measurements, allows for a change of paradigm in the way we confront tree epidemics. The response to tree disease outbreaks is mostly reactive, focused on monitoring, chemical treatments and tree felling, with the subsequent environmental and economic costs. Working alongside our partners (landowners, woodland managers, technological companies and policy makers), Fusion Forest will provide the means to prepare forests for outbreaks ahead of their occurrence, reducing critically mitigation costs. Forecasting pathways of transmission opens the door to new strategies to halt the spread of pathogens, that will no longer be assumed to be inevitable. Combining physical and biological barriers for pathogens in our forests is a ground-breaking idea, and Fusion Forest will generate tools and specific guidance to ensure this synergy.