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 Title Principal Supervisorsort descending Research Institutes Project Summary
HARP: High capacity network Architecture with Remote radio heads & Parasitic antenna arrays

Dr Tharmalingam Ratnarajah

Digital 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
A systematic study of physical layer network coding: From Information-Theoretic Understanding to Practical DSP Algorithm Design

Dr Tharmalingam Ratnarajah

Digital Communications

High spectral efficiency is the holy grail of wireless networks due to the well-known scarcity of radio spectrum. While up to recently there seemed to be no way out of the apparent end of the road in spectral efficiency growth, the emerging approach of Network Coding has cast new light in the spectral efficiency prospects of wireless networks [1]. Initial results have demonstrated that the use of network coding increases the spectral efficiency up to 50% [2, 3]. Such a significant performance gain is crucial for many important bandwidth-hungry applications such as broadband cellular systems, wireless sensor networks, underwater communication scenarios, etc.

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).

Measurement of pore wettability

Dr Xianfeng Fan

Materials and Processes

Pore wetting is a principal control of the multiphase flows through porous media. However, the contact angle measurement on other than flat surfaces still remains a challenge. In order to indicate the wetting in a small pore, we developed a new pore contact angle measurement technique to directly measure the contact angles of fluids and gas/liquid/supercritical CO2 in micron-sized pores under ambient and reservoir conditions in this study, as well as the effect of chemical functional groups on pore contact angle.

Particulate Materials Processing

Dr Xianfeng Fan

Materials and Processes

Bubbling fluidization has been widely applied in process industries, such as power generation from coal, renewable energy production, gasification and pyrolysis. In this study, we attempted to predict solid flow patterns, solid and gas mixing, bubble behaviour in a bubbling fluidized bed based on operational conditions and bed design.

Enhanced oil/gas recovery and CO2 storage

Dr Xianfeng Fan

Materials and Processes

Enhanced oil/gas recovery and CO2 storage are a displacement process at pore scale, in which oil and gas are displaced by water or CO2 in reservoir at pore scale, or water is displaced by CO2 in aquifers at pore scale. This displacement is controlled by pore structure, pore wettability, pore surface chemistry, fluid viscosity and interfacial interaction between pore fluids and pore surfaces. The displacement controls the pore connectivity, therefore oil/gas recovery and CO2 storage capacity. We investigate the displacement and the effect of various factors on the displacement at pore scale and core scale.

Development of UV and visible light active photocatalysts

Dr Xianfeng Fan

Materials and Processes

To address the need for effective vis response photocatalysts, we have synthesised WO3 and TiO2 nanowires to provide a fast transport channel for the photo-generated electrons which can retard the charge recombination. We are working on improving the visible activity of the catalysts through modifying the nanocomposites using metal (Ag, W, V, Fe, Ni) and non-metal (C, N, B, S) elements, and through the control over the microstructure or even over the crystal phase.

Clearwater: Demonstration of First Ocean Energy Arrays

Mr Henry Jeffrey

Energy Systems

This project will design, build, install and operate an open ocean 4.5MW tidal energy farm in the Inner Sound in the Pentland Firth, off the Northern coast of Scotland. The project ("Clearwater") will demonstrate the technical and economic feasibility of a multi-turbine tidal energy array, an essential step to catalyse development of commercial projects in the EU ocean energy industry. Project Clearwater provides a credible, robustly implemented transition from high cost single turbine demonstration deployments of marine turbines to economically viable multi-hundred turbine arrays in oceans and managed water assets across Europe and the wider global market.

DTOcean: Optimal Design Tools for Ocean Energy Arrays

Mr Henry Jeffrey

Energy Systems

DTOcean is a European collaborative project funded by the European Commission under the 7th Framework Programme for Research and Development, more specifically under the call ENERGY 2013-1.

IMPACT: Implantable Microsystems for Personalised Anti-Cancer Therapy

Professor Alan Murray

Bioengineering

IMPACT is a 5-year, £5.2M research project, funded by an EPSRC Programme Grant, to develop new approaches to cancer treatment, using implanted, smart sensors on silicon, fabricated in the University's Scottish Microelectronics Centre. IMPACT will use miniaturised, wireless sensor chips the size of a grass seed to monitor the minute-to-minute status of an individual tumour. This will allow RT to be targeted in space and time to damage cancer cells as much as possible. The team consists of engineers, chemists, veterinary clinicians, social scientists and human cancer specialists, led by Prof Alan Murray from the University's School of Engineering.

 

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