FLOWBEC - FLOW and Benthic Ecology 4D |
Dr Angus Creech
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Energy Systems |
The FLOWBEC project aims to improve the understanding of how the physical behaviour of the water such as currents, waves and turbulence at tide and wave energy sites influences the behaviour of marine wildlife, and how tide and wave energy devices might alter the behaviour of such wildlife.
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The Sc2.0 UK Genome Engineering Resource (SUGER) |
Professor Alistair Elfick
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Bioengineering |
Building the world's first synthetic eukaryotic genome together.
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Ground Penetrating Radar (GPR) Modelling |
Dr Antonis Giannopoulos
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Infrastructure and Environment |
Welcome to GPR Max, a ground penetrating radar simulation tool.
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Assessing and predicting the performance of GPR for landline detection using complete and accurate soil, target and antenna models |
Dr Antonis Giannopoulos
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Infrastructure and Environment |
The project's key objectives are to develop accurate 3D models of complex near surface soil formations and antenna design variants and so produce complete soil/system GPR models that can be used to assess and predict the performance of a GPR system.
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TEDDINET: Network of (Build) TEDDI projects |
Professor Gareth Harrison
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Energy Systems |
Established in September 2013 and funded for four years, TEDDINET is a research network examining the interactions of people with digital technologies and the potential for smart metering to transform energy demand in the home and at work. TEDDINET’s primary purpose is to create added value and enhance the impact of 22 individual research projects funded under the ‘Transforming Energy Demand through Digital Innovation’ (TEDDI) and ‘Transforming Energy Demand in Buildings through Digital Innovation’ (BuildTEDDI) programmes. Sponsored by the UK Engineering and Physical Sciences Research Council (EPSRC), these 22 projects encompass 26 (UK) universities, 75 partners from industry and the housing sector, and over 200 researchers from engineering, informatics, design and social sciences.
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Reduce energy penalty in CO2 capture processes and the emission of SOx and NOx from coal combustion |
Dr Xiangfeng Fan
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Materials and Processes |
The research focuses on develop a microwave swing technique to selectively heat solid at molecular level for adsorbent regeneration, and then compare the results with temperature swing. The project is supported by EPSRC.
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EcoWatt2050 |
Prof Vengatesan Venugopal
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Energy Systems |
The Scottish Government is committed to promoting substantial sustainable growth in its marine renewable industries. Agreements for sea bed leases are already in place for 2GW of wave and tidal developments, and projects are progressing through the licensing process. Strategic marine planning for future phases of wave, tidal and offshore wind development is now in progress. For marine renewables to significantly contribute to the low-carbon energy mix towards 2050, significant offshore development in the form of very large scale arrays will be needed.
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HARP: High capacity network Architecture with Remote radio heads & Parasitic antenna arrays |
Dr Tharmalingam Ratnarajah
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Imaging, Data and Communications |
To bring distributed multi-antenna wireless access to reality by combining two powerful emerging technologies:
radio remote heads (RRHs), which allow for widely geographically distributed access via radio-over-fibre connections to a central base station; and
electronically steerable passive array radiators – ESPARs, which provide multi-antenna-like functionality with a single active RF chain only
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Mixed Matrix Membranes for post combustion carbon capture of CO2 |
Dr Maria-Chiara Ferrari
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Materials and Processes |
Membrane processes are a promising alternative to the more classical post-combustion capture technologies due to the reduced maintenance of the process, the absence of dangerous solvents and their smaller footprint. This project aims at supporting the development of new mixed matrix membranes for post-combustion applications. Mixed matrix membranes (MMMs) are composite materials formed by embedding inorganic fillers into a polymeric matrix in order to overcome the upper bound and combine the characteristics of the two solid phases: mechanical properties, economical processing capabilities and permeability of the polymer and selectivity of the filler. Despite several studies on the concept, the interactions between the two phases and their effect on the transport properties are not well understood. Yet, this fundamental knowledge is crucial in order to design the reliable materials needed for real-world-applications.
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Educational & Training System for Clean Coal Technology |
Dr Maria-Chiara Ferrari
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Materials and Processes |
The general objective of CleanCOALtech project is: to create and develop an educational and training system for promoting, developing and implementing clean coal technologies, through knowledge and best practices shared from advanced EU country – UK to South-East European region – Romania and Greece in order to provide high performance and innovation in the vocational education and training systems and to raise stakeholders level of knowledge and skills.
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