Log in
The Cambridge University Centre for Risk in the Built Environment (CURBE) investigates techniques to identify, monitor and assess risk. Since 1997, CURBE's research contributed to real- world applications that reduce detrimental impacts of natural and manmade hazards, including the recent Haiti earthquake. Collaborators and users of the underpinning research include the British Council, the Government Office for Science, the US Geological Survey and Federal Emergency Management Agency in the USA, UN Habitat and private modellers and insurance companies involved in risk such as Risk Management Solutions and Willis Re.
Research performed at the University of Leeds allows the petroleum industry to reduce radically the amount of time that taken to estimate the key properties of tight sandstones containing natural gas. These properties largely determine whether gas fields are economically viable. Tests used in the past have taken between six months and two years to complete; with the Leeds research, results can now be obtained in less than one day — a radical improvement. Industry has used the results to justify drilling new prospects and to improve understanding of the controls on gas and water production in existing fields, which has shaped appraisal and production strategies.
Research on faults and fluid flow led by the University of Leeds has dramatically increased the ability of the petroleum industry to predict the impact of faults on fluid flow in petroleum reservoirs. The work has allowed the industry to reduce the risks associated with the exploration of fault- bounded reservoirs, and to identify areas of un-drained reserves in producing reservoirs. The research has won a series of important industrial and academic awards, and has provided a platform for the growth of Rock Deformation Research, a successful consultancy spin-out company whose turnover rose from £1.93 million in the period 2008-2010 to £4.0 million today.
Prof. White's research, and the associated computer algorithms he has developed,have played a key role in decision-making in the petroleum industry, particularly as the search for new resources has moved into increasingly hostile and remote regions on deep-water continental margins, where the uncertainty of exploration involves multi- million pound risks. The key to reducing the geological element of that risk is a detailed understanding of the structure and evolution of the thinned crust and lithosphere that underlie these margins. Prof. White's insights, algorithms and methodology are used by hydrocarbon companies, in particular BP Exploration, to predict hydrocarbon potential and to gain access to exploration acreage.
Full-waveform inversion (FWI) is a seismic technique for exploring the interior of the Earth; it has been developed at Imperial College over two decades, from a promising concept into a fully commercialised industrial process that has been widely adopted across the petroleum industry. The technique improves both the spatial resolution and the fidelity with which the sub-surface can be imaged in three dimensions. All the major multinational petroleum companies now use FWI internally, and all the major oil-field service companies offer the technology to the wider industry. Since its first commercial uptake in 2008, its application has influenced at least one hundred drilling decisions worldwide, and as a consequence it has generated additional value of at least $500M within the petroleum industry.
Resistivity anomalies resulting from hydrocarbon reservoirs can be located and measured using controlled source electromagnetic (CSEM) techniques. The University of Southampton played a pivotal role in the first full-scale marine CSEM survey over a hydrocarbon target in late 2000. This survey and subsequent work spawned one of the greatest technological advances in the field of oil exploration since the development of 3D seismic techniques. By the end of 2012 over 650 commercial CSEM surveys had been completed worldwide, with annual survey revenues in excess of US$200 million. The University continues to develop impact through consultancy and industry-funded research projects.
The Fault Dynamics Research Group (FDRG) have designed and executed analogue experiments to replicate the 3D/4D geometry of oil and gas exploration targets. The main beneficiaries are the international petroleum industry. The research is "pivotal to British Petroleum's subsurface developments" (R. Humphries BP 2012) in determining the number of multi-million pound wells required to access reserves. FDRG models "changed the way seismic data (was) interpreted" (Chief Scientist, Geoscience Australia 2012) in particular in the NW Australian frontier with "BP Exploration (Alpha)....work program(s) of $600 million" (Chief Scientist, Geoscience Australia 2012).
Approximately 70% of the continental margins contain significant volcanic flows, created when continents broke apart. Because large quantities of hydrocarbons may be trapped in sediments beneath the lava flows the ability to image through the basalt layers is of tremendous commercial value. However, these lava flows impede conventional seismic imaging by scattering energy, thus blocking the view of what lies beneath. Professor White and his team developed a technique, based on work in the 1990's, for imaging through the lava flows which differs radically from the conventional commercial approach. Professor White's technique has been widely adopted by the oil industry and has had a dramatic global impact, particularly for companies expanding exploration into deeper waters, including the north-west margin of Europe, the South American coast, particularly off Brazil and the continental margins of India. This approach has now become the norm having been adopted by oil companies globally.
UCL's Deep-Water Research Group (DWRG) creates knowledge transfer between research and the hydrocarbon industry. Oil companies use the DWRG's research results to generate improved in-house computer-generated hydrocarbon reservoir models, allowing them to manage, develop and value their reservoirs better. The same companies also use the research to run training courses for employees, including reservoir engineers and managers, leading to improved understanding and more informed decision-making about the management of hydrocarbon reservoirs. Improved management and development of reservoirs ultimately leads to oil companies being able to extract a greater amount of oil.
Newcastle University research on biodegraded petroleum systems has had a number of broad reaching impacts on the oil industry (ExxonMobil, Statoil, Woodside, and Shell), related companies (Permedia) and regulators (Alberta Energy Regulator). A new approach to oil viscosity determination was developed, which directs well-placement in biodegraded oilfields to lower viscosity areas, resulting in improved production of heavy oil. Software tools developed to model oil composition have been incorporated into proprietary in-house, oil company reservoir simulations. A spin-out company was founded, Gushor Inc., which provides services to the heavy oil sector and was recently acquired by Schlumberger. Collectively the research from Newcastle University has saved oil companies hundreds of millions of pounds by avoiding poorly producing viscous zones in biodegraded reservoirs.