Infrastructure is vital for society - for economic growth and quality of life. Existing infrastructure is rapidly deteriorating, the rate of which will accelerate with increasing pressures from climate change and population growth, and the condition of the large majority of assets is unknown. Stewardship of infrastructure to ensure it continuously performs its function will be a colossal challenge for asset owners and operators. The performance of new infrastructure assets must be monitored throughout their life-cycle because they are being designed and constructed to withstand largely unknown future conditions. The UK must be better prepared to face these grand challenges by exploiting technology to increase understanding of asset deterioration and improve decision making and asset management. This research is central to EPSRC's priority area of Engineering for Sustainability and Resilience. The goal is to transform geotechnical asset management by developing new, low-cost, autonomous sensing technologies for condition appraisal and real-time communication of deterioration. This new approach will sense Acoustic Emission (AE) generated by geotechnical assets. AE is generated in soil bodies and soil-structure systems (SB&SSS) by deformation, and has been proven to propagate many tens - even hundreds - of metres along structural elements. This presents an exciting opportunity that has never been exploited before: to develop autonomous sensing systems that can be distributed across structural elements (e.g. buried pipes, pile foundations, retaining walls, tunnel linings, rail track) to listen to AE - analogous to a stethoscope being used to listen to a patient's heartbeat - and provide information on the health of infrastructure in real-time. The idea to use AE sensing to monitor geotechnical assets in this way is novel - it is expected to lead to a disruptive advance in monitoring capability and revolutionise infrastructure stewardship. AE has the potential to increase our understanding of how assets are deteriorating, which could lead to improved design approaches, and to extract more information about asset condition than existing techniques: not only deformation behaviour, but also, for example, changes in stress states, transitions from pre- to post-peak shear strength, and using correlation techniques it will be possible to locate the source of AE to target maintenance and remediation activities. AE sensing will also provide real-time warnings which will enable safety-critical decisions to be made to reduce damages and lives lost as a result of geotechnical asset failures. The number of asset monitoring locations required per unit length to achieve sufficient spatial resolution will be less than other monitoring techniques, and significantly lower cost. Piezoelectric transducers, which sense the AE, are now being developed at costs as low as a few tens of pence per sensor - this recent technological advance makes this research timely. AE sensors could be installed during construction to monitor condition throughout the life-cycle of new-build assets (e.g. HS2), and retrofitted to existing, ageing assets. This will be the most fundamental and ambitious investigation into the understanding of AE generated by SB&SSS yet attempted. The findings will mark a major leap forward in scientific understanding and our ability to exploit AE in novel asset health monitoring systems. The fellowship aims to develop robust diagnostic frameworks and analytics to interpret AE generated by geotechnical assets. This will be achieved using a powerful set of complementary element and large-scale experiments. The outcomes will be demonstrated to end-users and plans will be developed with collaborators for: full-scale field testing with in-service assets to demonstrate performance and benefits in intended applications and environments; and implementation in commercial products that could have significant societal and economic impact.

Globally, one in four cities is facing water stress, and the projected demand for water in 2050 is set to increase by 55%. These are significant and difficult problems to overcome, however this also provides huge opportunity for us to reconsider how our water systems are built, operated and governed. Placing an inspirational student experience at the centre of our delivery model, the Water Resilience for Infrastructure and Cities (WRIC) Centre for Doctoral Training (CDT) will nurture a new generation of research leaders to provide the multi-disciplinary, disruptive thinking to enhance the resilience of new and existing water infrastructure. In this context the WRIC CDT will seek to improve the resilience of water infrastructure which conveys and treats water and wastewater as well as the impacts of water on other infrastructure systems which provide vital public services in urban environments. The need for the CDT is simple: Water infrastructure is fundamental to our society and economy in providing benefit from water as a vital resource and in managing risks from water hazards, such as wastewater, floods, droughts, and environmental pollution. Recent water infrastructure failures caused by climate change have provided strong reminders of our need to manage these assets against the forces of nature. The need for resilient water systems has never been greater and more recognised in the context of our industrial infrastructure networks and facilities for water supply, wastewater treatment and urban drainage. Similarly, safeguarding critical infrastructure in key sectors such as transport, energy and waste from the impacts of water has never been more important. Combined, resilience in these systems is vitally important for public health and safety. Industry, regulators and government all recognise the huge skills gap. Therefore there is an imperative need for highly skilled graduates who can transcend disciplines and deliver innovative solutions to contemporary water infrastructure challenges. Centred around unique and world leading water infrastructure facilities, and building on an internationally renowned research consortium (Cranfield University, The University of Sheffield and Newcastle University), this CDT will produce scientists and engineers to deliver the innovative and disruptive thinking for a resilient water infrastructure future. This will be achieved through delivery of an inspirational and relevant and end user-led training programme for researchers. The CDT will be delivered in cohorts, with deeply embedded horizontal and vertical training and integration within, and between, cohorts to provide a common learning and skills development environment. Enhanced training will be spread across the consortium, using integrated delivery, bespoke training and giving students a set of unique experiences and skills. Our partners are drawn from a range of leading sector and professional organisations and have been selected to provide targeted contributions and added value to the CDT. Together we have worked with our project partners to co-create the strategic vision for WRIC, particularly with respect to the training needs and challenges to be addressed for development of resilience engineers. Their commitment is evidenced by significant financial backing with direct (>£2.4million) and indirect (>£1.6million) monetary contributions, agreement to sit on advisory boards, access to facilities and data, and contributions on our taught programme.

As of April 2016, a total of 103,510 uniformed personnel from 123 countries were serving in 16 peacekeeping operations around the world. Where foreign soldiers - during war, occupation or peacekeeping operations - are on foreign soil, military-civilian relations develop, including those between soldiers and local women. Peacekeepers have increasingly been associated with sexual exploitation and abuse of the vulnerable populations they had been mandated to protect. Many of the intimate relations between peacekeeping personnel and local women, of both voluntary and exploitative nature, have led to pregnancies and to children being born. These so-called 'peace babies' and their mothers face particular challenges in volatile post-conflict communities, reportedly including childhood adversities as well as stigmatization, discrimination and disproportionate economic and social hardships. This project proposes an in-depth-study on the situation of 'peace babies' conceived by personnel from or associated with the United Nations Stabilization Mission in Haiti (MINUSTAH). MINUSTAH is among the missions associated with allegations of misconduct, not least related to sexual and gender-based violence and consequently the unintended legacy of children fathered by UN personnel. The UN has recently acknowledged that 'peacekeeper babies' exist. Yet, an evidence base relating to the welfare of children fathered by UN peacekeepers (globally or in Haiti) is virtually non-existent, and it is clear that the existing UN policies and support programs are inadequate. The proposed study addresses this critical knowledge gap through the following original contributions: - Theoretical contribution - analysing the lack of accountability of the UN and its personnel for children fathered by UN peacekeepers by introducing a victim-centred approach; - Empirical contributions: i) exploring the gender norms, and the socioeconomic, cultural and security circumstances that contribute to unequal power relations between UN personnel and local civilians; ii) mapping the whereabouts of 'peace babies' in Haiti through a situational analysis of the areas surrounding six UN bases and exploring the circumstances around their conceptions; and iii) investigating the life experiences of women raising children fathered by peacekeepers; and - Methodological contribution - using an innovative mixed quantitative/qualitative research tool, Cognitive Edge's SenseMaker, to provide a more nuanced understanding of these complex issues. The multidisciplinary collaboration between scholars from the University of Birmingham, Queen's University, Kingston, the Centre of International and Defence Policy, and Haitian-based Enstiti Travay Sosyal ak Syans Sosyal (ETS), along with civil society organisations, the Institute for Justice and Democracy in Haiti and Haitian-based Bureau des Avocats Internationaux, will address this knowledge gap and enhance our understanding of the challenges faced by peace babies and their families as well as the obstacles to accessing support. Beyond the core UK-Canada-Haiti partnership, the project will include further ODA-recipient countries (among others Cambodia, Bosnia, Liberia and the DRC) and in a final project conference will apply insights from Haiti to Peace Support Operations (PSO) more generally in discourse with academic and non-academic participants from other countries with extensive PSO experience.

MRC : Lampros Bisdounis : MR/N013468/1

Understanding the exchange of energy and gases between the earth's surface and the lower atmosphere is essential for answering many questions related to, e.g., the global carbon budget, ecosystem functioning, air pollution mitigation, greenhouse gas emissions, weather forecasting, and projections of climate change. However, uncertainties in carbon dioxide (CO2) and water vapour (H2O) budgets limit our ability to reproduce and project these exchange processes. Exchange processes are usually analysed based on micrometeorological measurements from tall flux towers, thought to be representative of large area averages. A limitation of this approach is that the actual source areas of these fluxes are not always known and that the impact of land-surface heterogeneity (at small or large scale) on the fluxes is not yet completely understood. The micrometeorological measurements of the major carbon flux networks around the world, such as Ameriflux, Canadian Carbon Program, CarboEurope (in which the UK plays a prominent role) and Oz-Net, are essential to validate global estimates of CO2 sources and sinks, to develop and validate land surface models and to understand the sensitivity of CO2 fluxes under changing climate conditions. Unfortunately, flux tower measurements currently suffer from substantial uncertainty, which is primarily due to the indeterminate relationship of fluxes and their source areas; at present our current understanding can explain 60-80% of the variance of the fluxes. The overall goal of this project is to incorporate information on topography and structure of vegetation (tree height, canopy depth, and foliage density) in footprint estimates and thereby substantially reducing the potential errors in the calculation of the CO2 and H2O budgets. The selected forested sites consist of the very few long-term flux stations within the boreal forest biomes and represent the three dominant species of the boreal forest (jack pine, black spruce, aspen). The combination of these three forest stands will provide data that is sufficiently representative to allow for upscaling to the boreal forest biome scale. The boreal forest constitutes the world's second largest forested biome (after the tropical forest) and plays an important role in regulating the climate of the northern hemisphere and in the global carbon cycle. The footprint model developed by the PI and widely used by the international community will be applied on long-term data sets to estimate the size and location of the area containing the sources or sinks (footprint) of CO2 and H2O fluxes measured at the three sites. The footprints will account for, and depend on, atmospheric conditions, such as wind speed and boundary layer stability, and surface characteristics, e.g. roughness. This footprint model is one of very few models that are valid over a huge range of stratifications and receptor heights. The major improvement of the footprint model will incorporate three-dimensional information on the structure of the forest, derived from airborne scanning LiDAR measurements, leading to exceptionally detailed high temporal resolution source information. Unlike data from passive sensors, the unique LiDAR data set provides information from within the tree canopy. The results will be used to analyse impacts of structure of vegetation and small changes in elevation on the net CO2 and H2O fluxes. The new understanding will assist future studies of upscaling from flux towers to the spatially heterogeneous boreal forest landscape and will reduce the uncertainty in the modelling of carbon budgets at local, regional and continental scale. It will lead to a greater understanding of local structural effects on carbon sources and sinks and thus the dynamics of carbon cycling and to major improvements of the description of these exchange processes in land surface models. Hence, the new insights will help reducing uncertainty in projections of climate change.