We are faced with meeting the agricultural demands of a growing population estimated to reach 9.8 billion people by 2050 on soils depleted of essential nutrients, with declining yields and a projected reduction in future rainfall in key agricultural regions. A circular economy between agriculture and organic waste streams can recycle essential resources for farming through the recovery of water, biomass, and nutrients from sanitation waste solids, effluents, and livestock manure at scale. This offers benefits to agroecological practices in farming by reducing the reliance on chemical fertiliser inputs with multiple benefits that improve soil health, reduce greenhouse gas emissions from farming, and reduce water pollution in drainage from fields. However, there are potential risks and challenges associated with this solution and these need to be fully understood to enable resource recovery to operate in a safe and sustainable manner in the long term. Firstly, the gastrointestinal tracts of humans and animals are a source of pathogens to the environment and agriculture food chain. So, reusing these wastes could potentially spread these pathogens to the food crops we consume. Secondly, manure and sewage are sources of veterinary and medical chemicals to the environment; these compounds can enhance a microbe's ability to resist treatment drugs, such as antibiotics. This ability to resist treatment drugs can spread to other microbes important for plant, animal, and human diseases. Antimicrobial resistance (AMR) is a global public health crisis that is predicted to cause 10 million deaths per year by 2050. Currently, livestock and the environment are recognised as reservoirs of antimicrobial resistant microbes and implicated in the dissemination of these AMR microbes. Science-based methods to assess the environmental, livestock and human health risks of combined exposure to antimicrobial selective compounds and AMR microbes are therefore central to fully realising the potential benefits of a sanitation-agriculture circular economy. Models, analytical tools, and quantitative assessment methods to understand, measure and assess the impacts of agricultural exposure routes urgently warrant scientific attention. Through understanding the safety risks recycling waste streams pose, new interventions can be devised to minimise these risks, making resource recycling a viable mechanism to increase soil and farm productivity. Working with water utility companies and the National Pig Centre, we will investigate how water and farm waste can be recycled to be used in agriculture. Using laboratory models, we will identify where pathogens and chemicals aggregate along the different waste streams, thus identify where interventions need to be made. Using this information, we will define a risk assessment analysis to tackle pathogen and chemical buildup. We propose to build on the 'one-health, one environment' approach to AMR by acknowledging the connectivity between humans, animals and the environment. This project will support the development of a UK sanitation-circular economy and build a UK-led innovation network with global reach. The overall aim of the project is to build a community of educational, industry, farming, and government colleagues to increase the capacity of the UK to address global pollution challenges associated with adopting a circular economy to support agricultural production. A circular economy approach is essential in meeting global agricultural needs, especially enhancing the role that farming can play in climate control and our need to move towards Net Zero greenhouse gas emissions. This proposal will pave the way in achieving this goal whilst minimising the impact of utilising waste materials on the environment and animal and human health.

Charles Darwin's great dilemma was why complex life in the form of fossil animals appear so abruptly in rocks around 520 million years ago (Ma), in what is widely known as the Cambrian explosion. During recent decades, exceptionally preserved animal fossils have been found throughout the Cambrian Period, which began 20 million years earlier, and arguably even through the entire, preceding Ediacaran Period, which directly followed the worldwide 'Snowball Earth' glaciations (~715 - 635 Ma). Most of these exceptional deposits were discovered in South China, which possesses the best preserved and dated geological record of the marine environment for this time. In this genuinely collaborative UK-China project, we propose to use the South China rock archives to construct a much higher resolution, four-dimensional (temporal-spatial) picture of the evolutionary history of the earliest animals and their environment. Towards this endeavour, our group combines complementary expertise on both the UK and Chinese research teams in: 1) geochronology - the dating of rocks; 2) geochemistry - for reconstructing nutrient and the coupled biogeochemical cycle (O and C); 3) phylogenomics - for making a genetically-based tree of life to compare with, and fill gaps in the fossil records; and finally 4) mathematical modelling, which will enable us to capture geological information, in such a way as to test key hypotheses about the effects of animal evolution on environmental stability. Our project aims to address three central scientific questions: 1) How did the coupled biogeochemical cycles of C, O, N, P and S change during these evolutionary radiations?; 2) Did environmental factors, such as oxygen levels, rather than biological drivers, such as the emergence of specific animal traits, determine the trajectory of evolutionary change?; and 3) Did the rise of animals increase the biosphere's resilience against perturbations? This last question has relevance to today's biosphere, as the modern Earth system and its stabilising feedbacks arose during this key interval. By studying it in more detail, and establishing temporal relationships and causality between key events, we can find out how the modern Earth system is structured, including which biological traits are key to its continued climatic and ecosystem stability. One further goal of this project is to strengthen existing and establish new, and genuinely meaningful collaborations between the UK and Chinese investigators. We will achieve this by working jointly in four research teams, by integrating all existing and new data into an international database, called the Geobiodiversity Database, sharing a joint modelling framework, and by providing collaborative training for the early career researchers involved in this project each year of the project.

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.

This project will focus on the central theme of Urban Narrative Environment, seeking to introduce recent research findings on narrative environment into the field of urban studies and to establish an international research network on this subject.\n\nToday we live in a world of cities: almost 50% of world population inhabits cities (89.7% in UK). 'It is vital that we understand the impact of this urban growth on people and the environment, as the links between architecture and society become both more complex and more fragile.' An understanding of urban conditions, including the conflicts, values and memory as well as human experience of them, necessitates multidisciplinary approaches and offers a challenge to the arts and humanities.\n\nNarrative is integral to human experience: on the one hand, we live in a world abounding with stories of various forms; on the other hand, narrative is one of the fundamental ways we organize and understand the world. Narrative is one of the prior schemes that are 'actively used to organize and interpret a person's encounter with the environment, both internal and external.' Narrative offers a distinctive approach to understand how our knowledge and experience of the environment is constructed and in return, how to organize the environment that conforms to human experience and memory and facilitates human interactions with the environment. \n\nThis project will examine urban environments through investigations into the interaction between temporally structured narratives and their spatial configurations, in other words, to investigate how 'space becomes charged and responsive to the movements of time, plot and history.' This project aims at revealing the hidden 'narrative landscape' in urban environments as a collage of narrative strata corresponding to the natural ways of experiencing an environment, namely gaze, route and survey modes. This 'narrascape' provides a particular layer to analyze and assess the values, organizations and representations of urban space. The concept and methodology of 'narrascape' will be developed through four multidisciplinary workshops with separate but correlated case studies. Digital media, especially moving images and virtual reality, with their extraordinary power in representing (and creating) human experience, will be employed and explored as the primary tools in presenting and developing urban 'narrascape'.\n\nThe Digital Studio is part of the Martin Centre for Architectural and Urban Studies, Department of Architecture, University of Cambridge. It is directed by Dr. François Penz and has for years successfully led EPSRC, AHRC and EU funded researches into narrative organization of space, non-linear narrative forms and the expressive use of digital media to facilitate design and communications on architectural and urban issues. This project seeks to extend Digital Studio's investigation into urban studies and to examine previous research outputs in the urban contexts of UK and China.\n\nThere is growing interest for UK and China to carry out research collaborations on the global issues of urban environments and urban conditions. The Martin Centre has strong track record of collaborative projects with Chinese universities on architectural and urban studies. This project will initiate a new network to bring together researchers and professionals from both countries to discuss and explore the narrative values, organizations and representations of urban environment. This project will consist of workshops, conference, translation and publication works, and dissemination activities. The foci are the workshops on the case studies of three historic cities: Cambridge in the UK, Nanjing and Changsha in China. Each case study addresses a sub-theme of 'narrascape'. Through these workshops, this project seeks to advance our understanding of urban narrative environment and to establish a network that will foster future research and practice opportunities.

Global agricultural production is required to double by 2050 to meet the demands of an increasing population and the challenges of a changing climate. Changing climatic conditions, including increasing temperatures, more variable precipitation, and drought are likely to put pressure on maintaining both high crop yields and a steady supply of food. On the other hand, assuming other factors are not limiting, rising atmospheric CO2 levels may lead to increased crop productivity, as the increased availability of carbon dioxide can promote enhanced rates of plant photosynthesis. The varying abilities of different crops or cultivars to adapt to water, temperature or nutrient pressures signifies the inherent resilience of a given agricultural system, and the likelihood and the degree to which they will be impacted by climate change. Understanding how current and future plant growth conditions affect crop yield is a major priority for ensuring food security, for adapting crop selection and management strategies and for guiding crop breeding programmes. The key challenge here is linking plant behaviour that can be measured at the leaf-level in the laboratory, to plant behaviour at the national or global scale, and predicting future behaviour under forecasted climate conditions. As environmental drivers operate and interact at multiple temporal and spatial scales, addressing this challenge will require transforming how we understand, monitor and predict plant responses to stress. Observations from satellites have revolutionised spatial ecology in recent years; making it possible to monitor ecological trends over large spatial scales, and to scale from the plant to the globe. Increasingly sophisticated instruments and techniques allow scientists to examine changing vegetation trends in response to climate change from satellites at unprecedented levels of accuracy. These advances have been made possible by sensor developments, an increasing archive of legacy satellite data, and new and emerging techniques such as solar-induced chlorophyll fluorescence, which has been shown to be closely related to plant productivity. Whilst still in its infancy, solar-induced chlorophyll fluorescence has shown potential to remotely monitor crop growth, using drones through to satellites. However, these remote sensing techniques must first be underpinned by a process-based understanding of the connections between the remote sensing signal and plant characteristics. In this research, controlled laboratory experiments will be used to understand how plant stress manifests in changes to the leaf biochemical and structural properties, and in turn, how optical reflectance signatures, can be used to measure these changes. These optical markers will then be used to 'scale up' our observations, first using drone technology at the field scale, and then and at national and global scales using satellite data. This remote sensing data on crop health will be used within sophisticated biosphere models to predict plant performance under current conditions and forecasted future conditions. These approaches in combination will provide a technological basis for a complete picture at different scales, to fully exploit the resources available for crop improvement. The overarching goal of the research is to assess the ability of nationally and globally important agricultural crops to maintain their growth and performance under different environmental stresses. This research will deploy a cutting-edge, cross-disciplinary approach using controlled growth chambers, novel remote sensing techniques and plant science methods to scale from the leaf to the globe, and provide a step-change understanding in the future pressures that crops may face in light of a changing climate and their underlying resilience.