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The 2010 eruption of Eyjafjallajökull volcano, Iceland caused prolonged closure of European airspace, costing the global airline industry an estimated $200 million per day and disrupting 10 million passengers. We have developed and tested models that predict the dispersal of volcanic ash and developed instrumentation to monitor ash clouds during flight bans and used it to test the models. Our research played a key role in establishing the need for a flight ban and in the adoption of a more flexible approach to its staged lifting as the emergency continued. It also led to increased levels of readiness and to new emergency procedures being put in place across Europe which have minimised the economic costs and human inconvenience without an unacceptable rise in the risks to passengers and crew. The new procedures safely eliminated unnecessary disruption to flights in the latter days of the crisis and during the subsequent eruption of another Icelandic volcano, Grímsvötn in 2011.
Nu Instruments is a successful mass spectrometer company set up in collaboration with geochemists at the University of Oxford. This joint effort was initially based around the development of a new kind of mass spectrometer; the Nu Plasma. Subsequent research in the UoA demonstrated the capabilities of this instrument for analysis of a large range of isotope systems, leading to its widespread use in geochemical and industrial laboratories around the world. Research in the UoA also aided in creation of new products, further contributing to growth in sales. Nu Instruments have sold over 150 instruments worldwide since 2008, while their turnover grew from £5.2M to £14.7M, and their employee numbers more than doubled to 105.
Our research since 1993 has led directly to demonstrable improvements in the physical representation of atmospheric particulates in the suite of Met Office numerical weather prediction (NWP) and climate models. These models have had enormous reach and significance across the REF period in both public sector and commercial Met Office activities. Our measurements impact directly on the model prediction of air quality, extreme pollution events (for fire brigade, police and public agencies), visibility, cloud cover, rainfall, and snowfall (for defence and the public weather service, commercial aviation, utilities, road and rail sectors).
Technology developed at UoM on clouds and aerosols proved vital in deriving ash mass concentrations during the 2010 eruption of the Iceland volcano, verifying the Met Office model that was defining the airspace exclusion zone and predict ash loadings for the Civil Aviation Authority. The shutdown of airspace cost the airline industry worldwide an estimated $1.7bn, reaching $400m per day on April 19th. Reassurance provided by our verification allowed lifting of flight restrictions which had the immediate effect of re-opening airspace, relieving the impact on hundreds of thousands of people globally, leading to an estimated global saving to the industry of $10bn The approach has resulted in new long term airborne response capability at the Met Office.
Research and knowledge exchange led by Prof. Jefferies in sustainable urban drainage systems (SUDS) has driven the design and integration of SUDS into urban environments, into urban planning and everyday practice in the UK, Europe and worldwide. This research has contributed to the development of policies and established guidelines that have informed the set-up of operational and monitoring systems and the reduction of a training manual which is impacting widely on the sector (downloaded >40.000 times). Evidence gathered through this research has supported drainage policy nationally and now underpins important parts of urban infrastructure, improving environments and their resilience to flooding.
Research by Lisa Emberson has led to tighter controls on air pollutant precursor emissions of ozone (O3) across Europe benefiting crop and forest productivity, and grassland species composition. Emberson's research led to new risk assessment methods, based on knowledge of atmospheric exchange processes and plant eco-physiology, which assess O3 uptake and related damage using novel flux-based `Critical Levels'. These new methods are being used to optimise emission reduction policy by 26 parties (member states) who have signed and ratified the United Nations Economic Commission for Europe (UNECE) Gothenburg Protocol established under the Convention on Long Range Transboundary Air Pollution (LRTAP).
Mathematically-based image processing techniques developed at the University of Cambridge have helped bring about a revolution in the ability to extract quantitative measurements from laboratory experiments in fluids. Techniques and software tools developed from this research and incorporated into commercial software are now used in engineering, physics and mathematics research laboratories around the world on projects ranging from fundamental research to ones with strong industrial connections.
Waltham's software, developed at Royal Holloway, is impacting on the oil and gas industry. For Statoil, one of the beneficiaries, it "influenced multi-million pound decisions" (Doré, Statoil Chief Geologist 2012) in their exploitation of the Gudrun oilfield, which required a £5 billion exploration investment. The software predicts the location of oil and gas reservoirs by simulating their formation by turbidity currents. The Royal Holloway software was commercialized by Midland Valley Exploration Ltd (MVE), used in consultancy work and sold to major oil-companies. Sales have generated £120k (Q3-2008 to Q2-2011) and created high-quality employment for three staff members at MVE.
For over 40 years, the Urban Pollution Research Centre has undertaken pioneering work in understanding the sources, behaviour and fate of urban diffuse pollution and its mitigation using sustainable urban drainage systems (SUDS). Relevant impacts claimed here include the adoption of SUDS into UK practice and legislation, the role of SUDS as key components in achieving EU Water Framework Directive (WFD) requirements and the embedding of our research within national best practice guidelines. In response to recent policy drivers, we are collaborating with Arup to commercialise SUDSloc and are informing policy developments in the fields of diffuse pollution mitigation and urban ecosystem services.
Biocatalysts provide unique activities that facilitate chemical transformations that are simply not possible using abiotic methods. Northumbria University researchers with expertise in enzymes and biocatalysis have provided biocatalysis services to the pharmaceutical, fine chemical, food and biofuels industries through our business facing innovation unit Nzomics. This has generated significant contract research, collaboration and licence agreements to companies, including the pharmaceutical company GlaxoSmithKline and the services-led company Almac. Biocatalysts produced as a result of Northumbria University research and technology transfer are sold worldwide and benefit business through their use in research and development activities, such as the production of intermediates in drug synthesis.