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Nanoco, is a University of Manchester spin out company having a current market capitalisation of £384m (31/7/2013). Nanoco's proprietary processes enable, for the first time, commercial quantities of high-quality quantum dot nanoparticles, free of toxic heavy-metals, to be manufactured economically — for incorporation into next-generation displays & solar-cells."
As a result of its world-leading disruptive technology, Nanoco has, in the REF period, forged down-stream global business partnerships that have generated around £11m revenue, creating 95 jobs with Nanoco (at a cost of over £3m/year), substantial secondary employment in the supply chain, and underpinning technology to enable the delivery of more energy-efficient electronic devices.
The research on the use of single source precursors in quantum dot synthesis undertaken by Professor Paul O'Brien in the Department of Chemistry at Imperial College between 1994 and 1999 resulted in papers and a patent which led to the formation of Nanoco Group PLC, currently a world-leader in the supply of quantum dots (QDs). Quantum dots have applications in backlighting for LCD displays, LED general lighting and thin film solar cells. Nanoco was listed on AIM on the London Stock Exchange in 2009 and by January 2013 Nanoco employed 78 people, had annual revenue of £3 million, and had signed agreements with several major companies in the US and Japan including Dow Chemical, Osram and Tokyo Electron.
The research underpinning Stephen Hawking's books, TV appearances and lectures has shaped public attitudes towards frontier research in cosmology. It attracts large audiences to learn about his research, and he is the most well-known scientist in the world. Highlights include the publication of his 2010 popular-science book The Grand Design, and the Discovery Channel series Into the Universe with Stephen Hawking. Further evidence of the impact of Hawking's research was the award of the 2009 Presidential Medal of Freedom (America's highest civilian honour) and his role as narrator in the 2012 Paralympic Opening Ceremony watched by over 11M UK viewers.
Surrey's Photonics Group has played a pivotal role in understanding and developing compound semiconductors for use in photonic devices. The strained-layer quantum well technology proposed and developed in their research is now incorporated in the vast majority of CD, DVD and blu-ray systems, in telecommunications and the internet, in computer mice, and in LEDs for solid-state lighting. Strained-layer quantum well lasers are manufactured by industry in their millions annually with a market value estimated in 2009 to be €15bn. Compared to the alternatives; these lasers offer greater efficiency, which has opened up new applications.
The Group's research has expanded to develop semiconductors for use in energy generation and combatting climate change, and in novel photovoltaics, low energy internet communications, and greenhouse gas detection. The research has led to engagement with the UK government's energy minister and has stimulated public discussion around the world.
This is an example of early economic impact where research on various aspects of laser engineering has resulted in the development of inexpensive, compact, efficient and user-friendly laser sources. An example is the incorporation of quantum dot structures into semiconductor laser architectures, with these replacing much larger and more expensive systems, with a range of applications in areas such as microscopy, biomedical diagnosis and therapy. This work has led to the generation of key know-how and patents that have been subsequently licensed as well as resulting in a variety of laser-related products being brought to market. Additionally, it has resulted in extra staff being employed at one of our partner companies.
Research in the Microelectronics Group of the Cavendish Laboratory in the area of single-electron nanoelectronics, quantum computing and spintronics has been exploited by Hitachi, one of world's leading microelectronics companies. Research breakthroughs made in the Cavendish have defined Hitachi's R&D directions in quantum computing and spintronics, led to several Hitachi product developments and influenced senior Hitachi strategic decision makers regarding the future of computing.
Our research on semiconductor materials and devices has led to the establishment by e2v Technologies of a combined manufacturing, research and development facility within the School of Physics and Astronomy. We have adapted and transferred device simulation software to e2v, and have provided epitaxially-grown semiconductors and access to fabrication facilities which have been used in their manufacturing processes. Devices fabricated within the facility, which was opened in 2011, have generated sales of £7M for e2v. This initiative has also led to shifts in the investment priorities of e2v, and mitigated risks to the company arising from import restrictions associated with the US International Traffic in Arms Regulations (ITAR).
This study describes two atomistic methods that have been used to explain better the behaviour and improve performance of materials. The research at Loughborough University from 2006-2013 has led to improved awareness and understanding in the areas of thin film growth and in irradiated structural materials for nuclear power. It has also led to changes in the operational models that Atomic Weapons Establishment (AWE) use. One of the algorithms developed has been incorporated into standard quantum chemistry packages, due to its increased accuracy and efficiency. The outcomes of the research have also contributed to changing UK government policy with regards to working with India in the area of nuclear research.
Thousands of exhibition visitors, public lecture-goers, readers, school students and TV viewers have been encouraged to explore areas of number theory and mathematical physics as a result of public engagement initiatives in four countries by University of Bristol academics. Lay people's encounters with the Bristol scientists have also changed their view of mathematics, mathematicians and the nature of their work.
Audiences have been reached through the Royal Society Summer Science Exhibition in 2011, a science fair in 2012, an award-winning Japanese TV documentary made in 2009, popular lectures given between 2008 and 2013 and contributions to popular science books.
Research on quantum mechanics, chaos and the Riemann Hypothesis is very appealing to members of the general public who have an interest in popular science. Bristol research ties these areas together. Its dissemination through various media has captured public attention internationally and inspired non-mathematicians to consider the mysteries addressed by mathematical research.
The commercialisation of Quantum Cascade Lasers (QCL) and the associated novel fabrication processes developed at the University of Glasgow has provided Compound Semiconductor Technologies Global Ltd (CSTG) with a new foundry product supplying quantum cascade lasers for gas sensing, safety and security, and military applications. This resulted in 40% turnover growth from 2010-2012 and the company is now recognised as a global leader in QCLs and their fabrication. Based on University of Glasgow research, the company has created a manufacturing toolbox for the production of a wide variety of QCL chip designs. CSTG has also achieved a world first, manufacturing QCLs for systems that detect explosives at a safe distance and can counter heat-seeking missile attacks on aircraft.