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The underpinning research involved modelling the diffusion of hydrogen on silicon surfaces, and the electronic structure of dopant atoms on silicon surfaces. This data was used to inform, guide and develop the atomically precise manufacturing processes of Zyvex Labs. These processes remove hydrogen atoms from a silicon surface to create patterns with atomic precision for later overgrowth. As a result of the UCL research, Zyvex Labs has already obtained funding of $14 million, several jobs have been created, and at least two products are being brought to market.
The UCL Department of Chemistry has for many years run a far-reaching programme of outreach and public engagement that has deep roots in the department's research programme. Its schools outreach work has promoted chemistry and science among secondary school children, while contributions to blogs, newspapers, radio, and television have engaged diverse audiences from primary school children to the elderly. Millions of people have viewed television contributions, while tens of thousands have been reached in theatres and science fairs, with positive reviews and feedback confirming a stimulation of public interest in, and understanding of, chemistry.
Researchers within the Department of Physics and Astronomy at UCL have investigated the properties of defects in bulk HfO2 and at Si/SiOx/HfO2 interfaces. Results have been used by an industrial partner, SEMATECH (SMT), to improve the quality and reliability of high-performance microelectronic devices based on transistors. This has helped SMT to meet project objectives on behalf of member companies such as Intel and IBM, and UCL research results have been consistently highly evaluated by these companies. Recommendations made by SMT have been implemented by industrial partners in their currently manufactured devices, such as the 22nm process technology released by Intel in 2011.
In 2011, a leading role was given to Peter Coveney in UCL's Department of Chemistry in defining the future strategy for the UK's e-infrastructure, based on the department's expertise and research in this field. This appointment led to the publication of the Strategy for the UK Research Computing Ecosystem document, which has since stimulated debate amongst policy makers and informed government policy. On the basis of its recommendations, the government has set up an advisory E-Infrastructure Leadership Council and allocated £354 million to improving the UK's high-performance computing capabilities and wider e-infrastructure, a move that is having wide-ranging industrial and economic impact in the UK. Most recently, in June 2013 the Strategy document stimulated further debate about the UK's e-infrastructure at the House of Lords.
A number of trimaran ocean-going ships, based on original designs conceived by UCL researchers, are currently in use. RV Triton, the demonstrator trimaran, is presently employed as a patrol vessel to provide Australian Customs and Border Protection with increased capability and lower fuel consumption compared to a monohull. The Independence Class of littoral combat ships currently entering service in the US Navy offers improved military capability and one-third lower fuel consumption, with the ensuing benefit of creating almost 2,000 jobs at the shipbuilder, Austal. Similarly, trimaran ferries with their inherent stability have improved passenger comfort and their reduced fuel consumption has lowered operating costs.
Catalysis is a major UK industry strength and wealth generator for the UK economy. Research carried out in the group of Professor Matthew Davidson in the Department of Chemistry at the University of Bath resulted in the development of titanium and zirconium alkoxide catalysts for use in three industrial polymerisation processes and patented by the UK companies ICI Synetix and Johnson Matthey. Patents have recently also been acquired by the Indian multinational Dorf Ketal and filed by the Dutch multinational Corbion Purac. The research has resulted in the adoption of new catalysts in industry leading to increased turnover, onward dissemination and implementation of the Bath intellectual property. It has also generated £4.6M from sale of intellectual property and an increase in generated sales of new, sustainable titanium catalysts that replace heavy metals such as tin, antimony and mercury in major industrial processes. The intellectual property and process developments have been implemented globally in the poly(ethylene terephthalate) (PET) and poly(urethane) (PU) plastics markets, worth $23B and $33B, respectively, in 2010.
Research at UEA over a 20 year period in the area of olefin polymerisation catalysis has had significant economic impact through:
The Department of Chemistry at UCL has pioneered the use of Raman spectroscopy (RS) for the identification of pigments in and the in situ examination of objects that are of artistic, cultural, or historical importance. Until recently this was a relatively unknown and rarely used technique in heritage science. RS is now used regularly by conservators worldwide and has become an important analysis tool in museums and libraries including the Victoria & Albert Museum, the Indianapolis Museum of Art and the Museum of Fine Arts in Boston. Collaboration between the British Library and UCL was highlighted by the House of Lords Science and Technology Committee, helping to promote further collaboration between universities and museums. The use of RS in heritage science has also benefited manufacturers of RS equipment, and has led to enhanced understanding of the histories and care requirements of a wide range of artefacts.
UCL research underpins Government requirements to monitor the effectiveness of its policies with respect to international legislation to combat the impact of acid deposition on surface waters. UCL led two programmes: the Acid Waters Monitoring Network and the Freshwater Umbrella programme. Since 2008 these programmes have been used to: (i) set national thresholds to identify the extent of acidification of surface waters; (ii) model and measure recovery of freshwaters from reductions in acid deposition; (iii) set new acidification standards for pollution of UK rivers; (iv) determine ecological status of key UK protected habitats; and (v) guide upland forestry planting.
A process for the commercial production of a family of Warwick-invented organometallic catalysts has been developed and patented by Johnson Matthey (JM). The catalysts — which have been sold internationally to several fine chemical and pharmaceutical companies in kilogram quantities, capable of producing tonnes of product — are in widespread industrial use for synthesis and scale-up. Other companies have protected, and are marketing, similar `copycat' catalysts. JM continues to work in collaboration with Warwick Chemistry on the next generation of catalysts.