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We have formulated and executed an extensive public engagement and outreach programme based on our leading technical and scientific involvement in the Herschel Space Observatory, a €1 billion astronomical satellite which was launched in 2009 and operated until April 2013. Herschel observed the Universe at far-infrared and submillimetre wavelengths with three scientific instruments, one of which (SPIRE) was built by an international team led by the Cardiff Astronomy Instrumentation Group, and Cardiff astronomers have been at the forefront in scientific use of Herschel and SPIRE. The beneficiaries of our PR and outreach programme include schoolchildren teachers, the media and the general public. The programme has achieved high exposure and impact locally, nationally and internationally. It provides inspirational personal contact and up-to- date material and information which has stimulated widespread and continuing interest in Herschel and also helped to raise the profile of STEM subjects, ultimately benefiting the economy.
3D scanning technology has enabled multiple opportunities for innovation in diverse areas such as manufacturing, design, and the arts. However, full utilisation of this technology requires not just the scanning hardware, but accompanying software that can build meaningful, editable models. This development has been pioneered by research conducted in the School of Computer Science and Informatics, at Cardiff University. Innovative algorithms for reverse engineering and digital shape reconstruction were devised that enabled the reconstruction of complex computer aided design (CAD) models from data captured by 3D scanners. The algorithms have been endorsed by Geomagic Inc, a market leading American software corporation (recently acquired by 3D Systems), that has subsidiaries in Europe and Asia and global distributors, and incorporated into their software product suite. This is accessed by nearly 10,000 licensed users worldwide, who have applied the product for industrial applications including aerospace and automotive engineering, product design, cultural heritage preservation, and healthcare. Accordingly, the impacts claimed are twofold: a) economic gain manifesting in the benefits to Geomagic and a plethora of end users who have utilised the software, b) impact on practitioners and professional services in diverse domains.
Platinum Group Elements (PGE) are critical strategic metals because of their unrivalled applications in catalysts, fuel cells and electronics and cancer therapies. Research and analytical methods developed at Cardiff have impacted on exploration for new PGE deposits, and more efficient processing of PGE ores by international mining companies. A key milestone between 2009 and 2012 was the discovery of a 3 billion year old giant impact crater in West Greenland. This discovery is of major economic significance because all craters previously found in this size class are associated with multi-billion dollar mineral and/or hydrocarbon resources. It led to an intellectual property transaction worth CDN$ 2.1 million and discovery of nickel and PGE deposits in Greenland by North American Nickel Incorporated.
The Space Robotics unit is heavily involved with the ESA/Roscosmos 2018 ExoMars rover mission, and is responsible for the radiometric and colourimetric calibration and image processing for two of the ExoMars science cameras during mission operations. Camera emulators have been built which has led to novel hyperspectral camera technology being developed. A terrestrial aerial version of this camera has been deployed in an unmanned aerial system (UAS) used for advanced remote sensing for precision agriculture applications. Impact on practitioners in this application area has emerged together with economic impact via Welsh Government funding. The ExoMars related research has led to impact in the area of society, culture and creativity.
The University of Southampton's distinguished body of work on the design of technology for gamma-ray detection and imaging has informed new counter-terrorism practices. Technological advances arising from the research have been crucial to delivering significant benefits in the fields of homeland security and nuclear safety — the latter particularly in the wake of the 2011 Fukushima disaster. A spin-out company, Symetrica, currently employs 26 people in the UK and the USA, has a forecast turnover of more than £10 million for 2013-14 and has been recognised as an example of best practice. It is a technological leader in the field of radioactive isotope identification.
Economic impact is claimed through the growth of the biopharmaceutical spin-out company Q Chip Ltd. During the REF period, this has created 19 new jobs, £7.5M investment, a new Dutch subsidiary (Q Chip BV), and staged-payment, six figure contract sales to four major international pharmaceutical companies.
Q Chip has generated over £928K in contract sales from the pharmaceutical industry from 2008-2012, with further sales of over £1M projected in 2013-14.
Originally established by Professor David Barrow in 2003 from his micro technology research, Q Chip has developed new processes and miniaturised equipment to encapsulate materials, including drugs, within uniform polymeric microspheres as injectable therapeutics.
A new family of antiviral agents, bicyclic nucleoside analogues (BCNAs), discovered in Cardiff University has led to a highly potent anti-VZV (shingles) molecule, FV-100. On a worldwide basis more than two million patients are affected by shingles annually. FV-100 has successfully completed Phase II clinical trials, showing it is safe, potent and effective and with clinical advantages over the current standard of care. FV-100 has received more than $30 million in R&D investment, generating patents and creating highly skilled jobs in the UK and the USA, with the parent company currently valued at $397 million. It will enter registration trials in late 2013.
Research led by the Cardiff University School of Physics and Astronomy has identified the world's earliest known astronomical calculator. The Antikythera Mechanism was discovered in 1900, in a Mediterranean shipwreck from the first century BC. However, its function and workings remained unclear until Cardiff University Astronomy Professor Mike Edmunds initiated and led an international research project. The results, showing that the mechanism was an astronomical calculator of extraordinary technical and mathematical sophistication, have revolutionised worldwide public understanding of key aspects of ancient Greek civilisation. Moreover, X-ray imaging technology specifically developed to analyse the mechanism, has generated approximately £15M turnover. The impacts are therefore extensive public engagement and significant economic gain.
Economic gains by oil and gas companies, improvements in professional practice in hydrocarbon exploration, and environmental benefits from identifying CO2 disposal sites have been achieved through a Cardiff-led consortium with industry. Building on research carried out since 2004, ten of the largest oil companies in the World have contributed to and benefited from understanding how faulted caprocks behave under specific geological conditions. Research at Cardiff has shown which families of faults and fractures make caprocks highly permeable, thus improving Industry's ability to predict if caprocks are able to prevent oil and gas reaching the surface.
Cardiff University's research has provided quantitative characterisation of transient fuel sprays under engine condition for the first time. This has enabled integrated design optimisation of Gasoline Direct injection (GDi) engines, through computer simulation validated by Cardiff's experimental measurements. The method has been developed and used in collaboration with Ricardo, a world-leading engine design consultancy, and has resulted in:
Economic impact
Environmental impact There have been substantial reductions in global CO2 emissions. Prior to 2012, GDi engine production had resulted in over 20M tonnes CO2 reduction globally, including 10M tonnes across Europe. A global reduction of 10M tonnes/year is predicted by 2020. Gasoline engines designed or developed by Ricardo in collaboration with Cardiff have provided a considerable contribution to this reduction. Cardiff's measurement techniques provided an essential step in designing these engines. For example, the PETRONAS engine uses 20% less fuel and produces 80% less NOx.
Improved Professional Engineering Practice Cardiff's experimental validation methodology has enabled Ricardo to design engines through simulation rather than step-wise empirical development, significantly reducing lead time.