Research Projects

All research projects at the School of Engineering. You can search keywords within Project title and filter by Research Institute.

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Project Titlesort descending Principal Supervisor Research Institutes Project Summary
TEDDINET: Network of (Build) TEDDI projects

Professor Gareth Harrison

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.

TIDES: Tidal Demonstration for Energy Scheme

Professor David Ingram

Energy Systems

A full tidal array has not been installed anywhere, commercially to date. A number of the leading turbine manufacturers have part or full scale working prototypes which are under-going testing in various sites the majority of which are enclosed in semi-test environments. In order to move this nascent technology into the commercial arena and expedite market deployment, it is necessary to establish an array of turbines in one site to verify the performance capability and environmental characteristics of a full array.

TOTALPHOTON: A Total Photon Camera for Molecular Imaging of Live Cells

Dr Robert Henderson

Integrated Micro and Nano Systems

How can we construct a high-resolution camera capable of imaging the time-of-arrival, polarisation and wavelength of each of the maximal 10Gphoton/s emitted from a labelled, biological cell? Such a measurement would capture the complete information available in the optical signal, and significantly enhance our ability to observe the organisation, movement and interactions of cellular components at molecular scales.

TRANSFER: Evaluation and Optimization of Fuel Treatment Effectiveness with an Integrated Experimental/Modeling Approach #2

Prof Albert Simeoni

Infrastructure and Environment

Over the past ten years, ca. US$ 5.6 billion has been spent on hazardous fuel reduction to treat an average of ca. 2.5 million acres per year across the United States. These expenditures represent one of the primary strategies for the mitigation of catastrophic wildland fire events. At the local scale, the placement and implementation of fuel reduction treatments is complex, involving trade-offs between environmental impacts, threatened and endangered species mitigation, funding, smoke management, parcel ownership, litigation, and weather conditions. Because of the cost and complexity involved, there is a need for implementing treatments in such a way that hazard mitigation, or other management objectives, are optimized.

TRANSPACC - TRANSient operation of flexible Packings for Carbon Capture

Dr Prashant Valluri

Materials and Processes, Multiscale Thermofluids

Power plants constitute one of the largest CO2 emitting sectors. With increased emphasis on abatement of emissions to meet the 2030 deadline set by the UK Committee on Climate Change, the power-plant sector is relying on CCS retrofits using post-combustion capture to clean up flue gases. However, despite the highly transient nature of power plant operation characterised by frequent shut-downs and start-ups (up to twice a day), the retrofits are currently designed for a constant base-load operation and hence cannot maintain even liquid distribution during unsteady loading.

TROPOS: Modular Multi-use Deep Water Offshore Platform Harnessing and Servicing Mediterranean, Subtropical and Tropical Marine and Maritime Resources

Professor David Ingram

Energy Systems

TROPOS is a European collaborative project funded by the European Commission under the 7th Framework Programme for Research and Development, more specifically under the "Ocean of Tomorrow" call OCEAN 2011.1 – Multi-use offshore platforms. The TROPOS Project aims at developing a floating modular multi-use platform system for use in deep waters, with an initial geographic focus on the Mediterranean, Tropical and Sub-Tropical regions, but designed to be flexible enough so as to not be limited in geographic scope.

Tackling the looming spectrum crisis in Wireless Communication

Professor Harald Haas

Imaging, Data and Communications

The proposed work in this EPSRC Fellowship is aimed at providing radical new solutions to this fundamental and far reaching challenge. A key pillar of the proposed work is the extension of the RF spectrum to include the infrared as well as the visible light spectra. The recent advancements in light emitting diode (LED) device technology now seems to let the vision of using light for high speed wireless communications become a reality.

TeraWatt: Large scale interactive coupled 3D modelling for wave and tidal energy resource and environmental impact (Remit 1 MASTS Consortium Proposal)

Dr Vengatesan Venugopal

Energy Systems

Scotland has substantial wave and tidal energy resources and is at the forefront of the development of marine renewable technologies and ocean energy exploitation. The next phase will see these wave and tidal devices deployed in arrays, with many sites being developed. Although developers have entered into agreements with The Crown Estate for seabed leases, all projects remain subject to licensing requirements under the Marine Scotland Act (2010).

The Development of 3-dimensional implantible liver organoids

Dr David Hay, MRC Center for Regenaritive Medicine

Bioengineering

The development of 3-dimensional implantable liver organoids, with the aim of providing alternative renewable solutions to organ transplantation in the treatment of human liver disease.

The Edinburgh Fluid Dynamics Group

Dr Ignazio Maria Viola

Energy Systems

The Edinburgh Fluid Dynamics Group (EFDG) webpage can be found below:  

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