As a signatory to the December 2015 Paris Agreement, India is committed to joining the global community in stabilising global temperature rise to well below 2 degrees Centigrade. Rapidly growing economies such as India are faced with the challenge of reducing emissions from the heavy industry and power sectors while ensuring continued economic growth. Carbon Capture and Storage (CCS), where CO2 is removed from flue gases and injected into deep geological formations for permanent disposal, is recognised by the IPCC as an essential technology for meeting climate goals at least cost. While high-level studies have identified some potential for CO2 storage in India, a perception remains that injected CO2 may migrate upwards from the intended storage reservoir towards the surface. Lack of fundamental research that addresses this issue prohibits detailed assessment of the potential for CCS to contribute to emission reductions in India. COMICS will establish an international partnership to understand the potential for safe and secure CO2 storage in India's sedimentary basins. The team comprises researchers from the British Geological Survey (BGS) and two leading Indian research institutes engaged in CCS, the Indian Institute of Technology Bombay (IITB) and the National Geophysical Research Institute (NGRI). A new £0.5M project announced by the Indian Government's Ministry of Science and Technology 'A systematic large scale assessment for potential of CO2 enhanced oil and natural gas recovery in key sedimentary basins in India' is led by IITB. The project comprises research groups; Indian Institute of Management Ahmadabad, Indian Institute of Technology Roorkee, and industrial partners; Oil and Natural Gas Corporation, National Thermal Power Corporation, Essar Oil and Gas, and the West Bengal Power Development Corporation. COMICS will complement the new Indian-funded project, combining local knowledge and expertise of the Indian consortium with the experience of the BGS CO2 storage research team. BGS has been active in CO2 research for over two decades, and undertakes related research in overburden properties, fluid-migration process, and monitoring requirements, funded by combination of UKRI (such as the current NERC Migration of CO2 through North Sea Geological Carbon Storage Sites, UK Carbon Capture and Storage Research Centre 2017) and EC H2020 projects (such as SECURe and ENOS). Our current research portfolio is worth over £5M. The COMICS project will extend these endeavours to include Indian data acquired through the new partnership, bringing new insights to CO2 storage processes in a region recognised as being vital to meeting regional and global climate ambitions. The project will initially focus on the Cambay Basin, where the Oil and Natural Gas Corporation have proposed a pilot CO2 injection project for enhanced oil recovery. The assessment of CO2 containment risks and monitoring and conformance requirements imposed by the specific geological setting are critically important. Based on the scientific research undertaken by COMICS, recommendations for safe and secure CO2 storage in the region will be developed. The research will underpin future research and development activities, including the development of new pilot CO2 injection studies. The results will also support nascent policy and commercial development of CCS through collaboration with industrial partners and state-owned companies engaged in the parallel Government of India-funded project. Facilitating CO2 emission reductions in India through targeted research activities is a key aim of COMICS. The proposed activities are aimed at securing future joint research opportunities for UK-India collaboration through Mission Innovation, existing UKRI programmes, and transnational UK Government (BEIS) funding to foster research and innovation related to accelerating CCS technologies.

The global hydrogen generation market is valued at $115.25 billion in 2017 and is projected to grow to $154.74 billion by 2022 [Global Outlook & Trends for Hydrogen, IEA, 2017]. We are witnessing significant market opportunities emerging for hydrogen technologies today. New and existing hydrogen technology developments and market activities are projected to intensify over the coming decade. Sustainable hydrogen solutions are a key pathway for decarbonising transport, heat and power generation sectors. Common challenges to sustainable hydrogen being adopted across these sectors are: - Cost reduction - Safety - Systems level and multisectoral innovations - Managing change Over the next decade innovative solutions are needed to tackle the above challenges, but it will be impossible without a dedicated mechanism to train doctoral Energy Innovation Leaders. These leaders should have a firm grasp of the technology from scientific fundamentals through to applied engineering and a solid understanding of the techno-economic barriers and an appreciation of the societal issues that will impact on the translation of disruptive technologies from research labs through to market. This goes beyond being multidisciplinary, but is a transdisciplinary training, reflecting the translation steps from understanding market driven needs, planning and conducting appropriate basic and applied research to products/solutions/system development through to successful market penetration. This is delivered by a cohort training approach through the cross fertilisation of ideas of a cohort with a diverse background, peer-demonstration of the value of research across a diverse range of stakeholder-led projects, thus facilitating a peer-to-peer transdisciplinary learning culture. The SusHy Consortium, led by Gavin Walker, continues a long running and highly successful collaboration in hydrogen research between the Universities of Nottingham, Loughborough, and Birmingham (UoN, LU, UoB) which started over a decade ago with the Midlands Energy Consortium. The Midlands Energy Graduate School spawned two successful CDTs (Hydrogen, Fuel Cells and their Applications and the current Fuel Cells and their Fuels). The current proposal for a CDT in Sustainable Hydrogen brings together the world leading expertise in hydrogen generation, purification, sensors/monitoring, and storage, along with whole systems issues (resilience engineering, business economic models and life cycle analysis) which exist across the three Universities. A gap in the consortium expertise is in the research field of hydrogen safety and we identified the internationally-renowned Hydrogen Safety Engineering and Research Centre (HySAFER) at Ulster University (UU) as the right partner to deliver on this key aspect. This is the first broad collaboration in the world seeking to investigate, train researchers and produce leaders in Sustainable Hydrogen. Stakeholder Partnerships. A key strength of this CDT is the active involvement of the Stakeholders in co-creation of the training programme which is reciprocated in the value with which the Stakeholders view of the CDT. This shared vision of a training partnership between the Universities and Stakeholders will lead to the smooth function of the CDT with not just a high-quality training programme, but a programme that is tailored to the sector needs for high-quality, industry-ready doctoral Energy Innovation Leaders. The valued CDT-stakeholder partnership will also be a significant appeal to candidates interested in energy-related PhDs and will be used to help market the CDT programme to a diverse talent pool.

Increasingly, the places we inhabit and move through - our homes, stations, cafes, offices and the like - will have embedded Internet-of-Things (IoT) devices. These will enable us to be provided with content, communicate, have our environments sensed and adjusted, and so on. While this is a compelling (and very useful) future vision, the energy demands it brings are enormous. Furthermore, we risk cluttering up our physical environments with a plethora of digital devices. In the 'developed' world these are problems that will affect sustainability and the quality of our built environments. In the 'developing' world, though, energy resource constraints and physical resource issues means that without innovation, billions of people will have reduced opportunities to benefit from the coming IoT revolution. This project is about trying to capture the benefits of the IoT future while making it sustainable, delightful and universally accessible. The work involves a team of material scientists and human computer interaction researchers, working together with partners to develop a new form of physical material that can generate the power it needs to drive digital interfaces and interactions. That is, we will drive towards attractive, flat and flexible solar energy harvesting tiles (Photovoltaic - PV - tiles), which may incorporate input and output features to enable people to interact with them and other connected devices. These tiles will be able to be integrated into buildings (in walls and floors, for instance) and objects (like tables, clothes and book covers). The surfaces capture the energy from indoor and ambient light and at the same surface can present digital displays and interfaces to the user. To illustrate the possibilities, consider the following four user-centred scenarios: 1. Tom is busy in the kitchen. A set of Interactive-PV tiles, built decoratively into the wall along the kitchen surface, activates to show a silhouette of a figure approaching the front door. Tom is waiting for a delivery, so gestures at the tiles - the delivery driver at the entrance is shown a message on the door number PV tile, asking her to leave the parcel in the porch. 2. Shashank is walking through the narrow streets of a slum in Mumbai during the monsoon rains. He approaches an awning protecting the street from torrential rain and gestures at a flexible Interactive-PV tile woven into it. The tile displays a no-entry warning sign, and he decides to change direction to avoid walking into a deep flood in the passageway ahead. 3. Sarah has created some interactive art designs for her bedroom wall. She sends them to the Interactive-PV display tiles she has had installed, and later enjoys them, especially as they show her the external weather forecast in a personalised way. She's happy that while they work like LED displays, they can operate for years without needing external power, battery changes or space-consuming standard PV cells. 4. Sofia has flexible designer Interactive-PV tiles on her dress that she uses to control a music player or smartphone with hand gestures, and to receive alerts via electro-tactile feedback. She's impressed that the interface works in a range of environments and light conditions as she moves from her house, through the underground metro system and later to a mellow lit bar. The project ideas and the work itself as it progresses have been co-created with UK and global industry partners and a centre in India that has over 40 years of providing insights into design for resource-constrained communities.

This Fellowship is about re-orientating interactive AI systems, away from systems that might lead to people feeling powerless, redundant and undervalued, turning towards approaches that let people experience joy, creativity, connection and agency as they use AI innovations to amplify their innate abilities, qualities and values. Many everyday people worry about the impact of artificial intelligence on their lives and livelihoods. In the most recent Stanford AI-100 report (September 2021), for example, while the fear of robots taking people's jobs has reduced, there is a strong concern that such systems will erode democracy and values through deep fakes, manipulated social media feeds and the like. The report points to Grand Challenges for AI that involve systems outpacing or outsmarting humans. Even as I write this summary (late Jan 2023), there is a frenzy of excitement over Open AI's ChatGPT, a system that can turn a simple written request (e.g. "Write me a compelling EPSRC summary") into, at least at the surface level, a seductively articulate response (N.B., this summary is definitely written by me). Further, I am writing this while in South Africa where I have engaged with community members in Langa, a township on the outskirts of Cape Town, South Africa, as part of the preparation for the Fellowship. These people spoke of the starkly real problems (from violent crime to very high unemployment). With so many underserved and unheard voices, globally and indeed in the UK, there is a timely and urgent need to think about how to radically enable these "natural intelligences" rather than to replace them with artificial ones. In this Fellowship, then, we will work intensively with people who are not usually involved in AI discovery and innovation - people with lower socio-economic opportunities in the UK and those in Global South communities such as the informal settlements in India, Kenya, Brazil and South Africa. Their lived-experiences will be brought into the design and development process, a process further richly enhanced through the involvement of a diverse set of technology, service provision and creative partners. In doing so, we aim to discover novel ways for people - everywhere, whatever their contexts and opportunities - to engage with AI systems. We call this new trajectory for AI research, EVE - everyone virtuoso everyday - to succinctly summarise the drive of the work. That is, we are interested in defining and evaluating a class of AI technology that enable expressive, individual and masterful interactions, like a virtuoso musician who channels all of their being - physical, mental, emotional and even spiritual - through their instrument to help themselves and others make sense of the world. However, our work is not about turning everyone into an AI-fuelled artist, dancer or musician. Quite the contrary, we look to providing tools that can be deployed in the mundanity of their daily lives. As a Fellowship, the vision and agenda is broad and open to continuous shaping with communities, academics and wider societal stakeholders as the work proceeds over three cycles, each 20 months long, as ideas move from seeds of possibility, growing and being refined into working embodiments, enabling us to evaluate them, integrating them into toolkits for wide impact in academic and practice worlds.

Sustainable urbanisation requires the provision of secure energy for health and comfort. Key to planning sustainable energy services is an understanding of how energy demand changes over time and space and tools to help plan for its reduction. iNUMBER is a research programme to develop: 1. A building stock and municipal service energy model to help plan a secure energy supply for urban populations to be thermally comfortable and healthy (via the provision of clean water and sanitation). The model will estimate total and disaggregated (in use, time and space) energy demand. Plus, assess the impacts of different mechanisms (e.g. shading, occupant behaviour and insulation) to reduce energy demand and the capacity to provide locally generated clean energy. 2. Linked new and existing data sets. Developing models is relatively simple, the challenge is acquiring the data to input and test the validity of models. iNUMBER tackles this challenge head on by developing state of the art data collection and analytic methods to overcome this challenge in a range of scenarios with different data availability. 3.Tools to help support the urban energy management process iNUMBER supports Indian municipalities and local partners to develop a data-driven intelligent urban model for built environment energy research and municipal planning. It supports India's deep decarbonisation pathway by mapping current and future energy demand reduction opportunities in the built environment. It will diagnose urban energy problems, test solutions, verify progress, and improve policy decisions utilising state of the art monitoring, data science and analytics. iNUMBER primarily focuses around meeting the India/UK Newton research topic "Integration of information, communication and renewable energy technologies at building, community, and city level interventions." and will also meet elements of the other two areas of the call "peak demand reduction" by contributing new high resolution data and "city and community technologies" by providing guidance to urban planners iNUMBER will: -Undertake innovative research into: urban data collection (e.g. laser ranging combined with IR and visible images from unmanned vehicles), big data analytics, and innovative modelling. -Promote the economic development of and welfare of developing countries, as required by Newton funding, by helping India to transition to a smart sustainable energy system which is critical to economic development. -Engage users of different types. Our initial project partners include urban local bodies, energy software developers, energy meter hardware suppliers, residential construction companies, architectural firms, and user experience experts. Beyond these immediate partners, we will coordinate and collaborate with other research groups in the field, engage with policymakers, and benefit the public. -Leverage Newton and DST funding by ~£1m, with support from host universities and project partners who will provide data, test sites, equipment, and provide sector expertise. -Demonstrate usable solutions: online energy information systems; benchmarking backed up by large data sets; low-tech "smart-er" retrofits for electricity meters and sub-meters; reduction strategies for energy and the energy-water nexus tailored to cities of different shapes and sizes. -Build a collaborative India/UK interdisciplinary research project: This proposal builds on the strengths of India in Information Technology and the strengths of the UK in energy epidemiology to build a best with the best collaboration. The team includes leading academics from engineering, data science, information technology, energy analysis, architecture, building science, urban science, urban planning, energy management from leading institutions in India and the UK. All work packages will be delivered via teams from both UK and India and many work packages involve interdisciplinary collaboration.