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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.
Statistical research undertaken by the Industrial Statistics Research Unit (ISRU) at Newcastle University has led to improved accounting of gas in the national transmission system provided by National Grid. A discrepancy, known as unaccounted for gas (UAG), results in accrued costs and potentially unfair billing. In 2009/10, UAG is estimated to have cost £100 million. National Grid has adopted our research results by making fundamental changes in their data utilisation with benefits that reach all the distributers and users of gas throughout the UK. In 2010 our methods helped identify a source of UAG, resulting in £14 million being returned to the community. Our reports inform decisions made by regulators and provide data-based evidence to support negotiations between national transmission, local distributors and users.
New commercial gas sensing technology developed from research at the University of Strathclyde brings extensive technical, operational, safety and cost benefits to applications such as mine safety and leak detection in methane production, storage, piping and transport systems. World-wide commercial sales (in Japan, China and the USA) began in late 2010 through a spin out company, OptoSci Ltd. Sales are growing and have amounted to a total of £250k since launch plus a customisation contract for £193k, leading to jobs sustainability and growth. In addition to economic impacts, the technology also brings health and safety benefits in the gas distribution and mining industries through human safety assurance in the event of gas leaks / build up.
Research at the University of Manchester has led to the provision of cost effective instruments for monitoring water, industrial and environmental pollution. The underpinning research on chemical sensors conducted in the unit was protected by patent, and in 2007 Multisensor Systems Ltd was spun-out in-order to meet the needs of the water industry and has grown to employ 6 people in 2013. Currently this is the only commercially available instrument sensitive enough to monitor low concentrations of hydrocarbon pollution and is used by major UK water companies to prevent risk of environmental pollution hazards with mitigated losses valued at more than £100m.
The performance of absolute distance measuring systems has been improved in terms of accuracy, traceability, reliability and cost through the introduction of new methodology arising from research at the University of Oxford. This has brought commercial benefit to a German company making measurement systems, through the creation of a new product line. New capabilities for measurement have been delivered to a first customer in Germany. The research has also resulted in the establishment of new activity at the National Physical Laboratory, and influenced UK and European technology roadmaps for future manufacturing.
The first commercial electronic nose (aka e-nose) instruments were designed, developed and built by researchers in Warwick's School of Engineering in the 1990s, and commercialized by [text removed for publication]
Warwick's patents in chemical sensing also led in 2008 to the creation of a spin-out company, Cambridge CMOS Sensors Ltd (CCS), which provides low-cost low-power gas-sensing technology and is already established in the gas-sensing market.
The smart sensors and instrumentation developed as a result of the pioneering research in artificial olfaction and chemical sensing have had economic impacts across a wide range of sectors, in particular in food quality, healthcare and consumer electronics. The two companies employ around 100 people and the thousands of e-nose instruments sold help quality assurance of foods, beverages and are now being deployed in hospitals for bacterial detection.
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.
[text removed for publication], a developer of high-precision medical devices, have produced a new data annotation tool ([text removed for publication]) based on research in CSRI on data storage formats and activity recognition for applications within smart home environments. Within [text removed for publication] stereo-based cameras record activities in a specified environment (e.g. kitchen) which are then annotated using user-based pre-configured activity labels (e.g. prepare meal, wash dishes). [text removed for publication] is currently used by [text removed for publication] users and has yielded additional sales worth [text removed for publication]. [text removed for publication] have employed [text removed for publication] additional technical development staff to extend [text removed for publication] functionality, and through an MoU [text removed for publication] now supports automated annotation based on CSRI's research on activity recognition.
ERPE research led to the following impacts in the REF2014 period:
Measurements of sulphur dioxide emissions from volcanoes provide critical evidence for forecasting eruptions. From 2001 the research team led by Clive Oppenheimer (Department of Geography, University of Cambridge: Lecturer 1994-2003; Reader 2003-12; Professor 2012-) has shown that a new technique based on UV spectroscopy can revolutionise such measurements. The approach (awarded a US patent in 2006) has since 2008 come to underpin the state-of-the-art in operational surveillance of volcanic emissions worldwide, contributing significantly to hazard assessment and emergency management at over thirty volcanoes, and helping to save lives by providing early warning. The team has trained and supported volcanologists around the world in the methodology (in Costa Rica, 2008; Java, 2010; Iceland, 2012), and has helped in collecting data during volcanic crises (e.g. Merapi, 2010), contributing to planning decisions and the safety of local populations.