Log in
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.
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.
Research focussed on understanding volcanic degassing and developing monitoring methods to forecast volcanic activity forms the basis of this impact case; this work was carried out by a group of academic staff and early-career researchers based in Cambridge. The arrival of large fluxes of sulphur-rich gases at the surface can be used to assess magma movement and forecast volcanic activity. This assessment feeds into local governmental decisions regarding risk mitigation and development planning, and the viability of commercial enterprises requiring access to volcanic areas. The development of automatic spectrometer networks for monitoring sulphur dioxide emissions was pioneered by this group. The prototype system was developed at Soufriere Hills Volcano, Montserrat and since then, the design has been patented and adopted at 20 volcano observatories worldwide.
Impact: Public and private sector investment in technologies for Carbon Capture and Storage (CCS), including a major UK Government CCS Commercialisation Programme.
Significance and reach: In the 2010 Spending Review the UK government re-affirmed a £1billion commitment to CCS funding, which since 2012 has been referred to as a CCS Commercialisation Programme. [text removed for publication]. The European Commission have placed CCS pipelines into 2012 infrastructure package negotiations, with allocated funds of ~ €2.5billion.
Underpinned by: Research into the sub-surface storage of carbon, undertaken at the University of Edinburgh (1999 onwards).
Our research has had a global impact on understanding the tectonic development and fill of rift basins, providing a predictable spatial and temporal template for the distribution of hydrocarbon reservoir rocks. The models are embedded in exploration workflows of global oil companies and have influenced recent exploration success (North and East Africa, Atlantic conjugate margins). Translational research on 3-D rift basin outcrop data capture and resulting software licencing has improved reservoir modelling, optimising positioning of $100m wells. Field-based training for several hundred oil industry staff since 2005 has ensured in-depth knowledge transfer.
Thermally sensitive polymers are injected into oil reservoirs to increase the recovery of oil. Experimental and theoretical modeling carried out at the BP Institute, University of Cambridge, has led to a new understanding of the behaviour of such polymers and increased their effectiveness in recovering oil, through improved design of the injection, and led to the discovery of a new reservoir monitoring technique to detect their effect on production. Optimising injection of polymer increases well production by over 1000 bbl/day and has generated annual revenues of over $US 300 million. This technology is also being applied to thermal energy storage systems.
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.
A new company, Geomerics, was created as a spin-out from the Cavendish Laboratory. Geomerics now employs 22 full time staff, with offices in Cambridge, UK and Vancouver, Canada. Geomerics has pioneered a new business sector in selling lighting middleware technology, based on Cambridge research, to games developers. Customers include Electronic Arts, Square Enix and Take 2 (three of the five largest publishers) and licenses have been sold in Europe, North America, Japan and Korea. In 2011 the first game released using Geomerics software, Battlefield 3, became the fastest selling game in Electronic Arts' history, having sold nearly 20M copies.
Research on the Shahnama and the Cambridge `Shahnama Project' have stood at the head of a wider effort to promote a better understanding of Persian culture in Britain and the West, especially in view of the current negative image of Iran and its clerical regime. The impact has been (1) to enhance heritage activity in Iranian diaspora communities in the UK and elsewhere; (2) create a focus and catalyst for raising awareness amongst the wider British public of Persian culture and history, and of past relations between Britain and Iran; and (3) inspire and support new forms of artistic expression.
Impact: Economic benefits have been derived from the MTEM Limited spin-out company, which has been owned since 2007 by Petroleum Geo-Services (PGS). These include a commercial marine application of the MTEM (Multi-Transient ElectroMagnetic) method offshore Tunisia in 2008, successfully discovering hydrocarbons before drilling and the 2012 launch by PGS of a fully-towed commercially-viable marine MTEM system.
Significance and reach: Approximately 180 man-years of employment, with a value of more than $15M, have been provided in Edinburgh over the period January 2008 — December 2012.
Underpinned by: Research into electromagnetic survey methods, undertaken at the University of Edinburgh (1999 onwards), which led directly to the creation of MTEM Limited.