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Interdisciplinary research on a new class of organo-metallic light emitting polymers showed that they could produce white light very efficiently. A consortium of the University and Industry (predominantly Thorn Lighting, the largest lighting manufacturing employer in the North East) developed and patented these into a viable alternative to mercury vapour fluorescent lights with a £4.3M grant from the DTI with matched funding from industry. The companies are investing in scaling this up to a full commercial supply chain, supported by a £4M grant from the Technology Strategy Board. The success of the project helped BIS secure £20.5M to support Plastic Electronics in the UK, creating 26 jobs, and was cited as a factor in the Thorn decision not to close down its North East site, safeguarding 600 jobs.
Impact: Economic The light-emittingdendrimers are a new class of materials for organic light-emitting diodes, a major display technology. They have been commercialised by Cambridge Display Technology (CDT), the leading developer of polymer light-emitting diodes.
Significance Light-emitting dendrimers provided a breakthrough in the efficiency of organic light emitting diode (OLED) materials deposited from solution. This enabled the convenience of solution-processing to be combined with high efficiency, and enabled solution-processed materials to compete with evaporated materials.
Beneficiaries CDT, display manufacturers around the world and display users.
Attribution The research was performed by Professor Samuel in collaboration with Professor Burn of the University of Oxford.
Reach Materials based on light-emitting dendrimers are manufactured by Sumitomo Chemical in Japan and supplied to global displays manufacturers.
A public engagement campaign based around 15 years of natural photonics research at Exeter University succeeded in enthusing school-age children in a science that was suffering declining levels of interest. Professor Pete Vukusic gave a series of lectures that brought the science of light and colour to life for 17,000 students and 1,500 teachers across the UK, Ireland and Africa, and subsequently a global audience of thousands via YouTube. His work played a central role in the Institute of Physics' efforts to promote the value of physics in the UK and overseas, contributing to a marked rise in the number of students taking physics A-level. In 2013, Vukusic was awarded the distinguished Royal Society Kohn Award for Excellence in Engaging the Public with Science.
Natural photonics research by Professor Pete Vukusic at the University of Exeter was responsible for shaping the successful global communications strategy of Bausch & Lomb, a world-leading supplier of eye health products. Drawing on Vukusic's studies into bio-inspiration, Bausch & Lomb built its core brand messaging for a major new lens product around the ability of nature to inspire technological breakthroughs. Outreach campaigns targeting media and optometry professionals took Vukusic's research to an international audience, raising wider public awareness of the concept of bio-inspiration. Bausch & Lomb attributed their subsequent rapid sales growth to Vukusic's work.
Impact: Health and Economic Gains:
Research has led to a wearable light source that provides a new way of treating many skin cancers and acne. The treatment is safe, convenient, and easy to use bringing benefits to patients and healthcare providers. In addition it brings economic benefits to Ambicare Health Ltd, the company commercialising it.
Significance
For skin cancer treatment, the device gives effective treatment with much reduced pain. The simplified treatment procedure allows more patients to be treated in a clinic session. For acne, the device provides a convenient at-home treatment without the application of drugs or chemicals.
Beneficiaries:
Skin cancer and acne sufferers, the clinics that treat them and Ambicare Health Ltd.
Attribution:
The work was led by Professor Ifor Samuel (PHYESTA) working with Professor James Ferguson (Ninewells Hospital, Dundee).
Reach:
The wearable light source has changed treatment in the UK and the Netherlands. The skin cancer treatment is in regular use at more than 25 clinics, and the acne treatment at more than 250 clinics.
Covesion, a company that was spun out of the University of Southampton, focuses on research and development of high-value engineered nonlinear crystal materials, that find widespread use in the laser, defence and display sectors. The impacts of their work fall under the headings of economic, via job creation and investment, health, through application of their products in medical imaging, and the environment, via detection of airborne pollutants and remote sensing. The company is now a multi-million pound business that has attracted more than £1m in US investment and won UK export orders around the world. The global value of Covesion-enabled commerce since the company's inception in 2009 is estimated to be in excess of US$100m.
Researchers, and the work they undertook at the University of Exeter during the 1990s, led to the formation of the Defence Evaluation and Research Agency's (now QinetiQ) first spinout company: ZBD Displays Ltd. Achieving revenue growth of 17,910% over the last five years, ZBD's unique electronic retail signage and shelf-edge labelling technology is used by major retailers all over the world. The invention used the know-how developed by ZBD's company founders whose R&D and engineering teams all include former postgraduates from the School of Physics and Astronomy, who acquired their expertise under the supervision of Professors Roy Sambles and Bill Barnes.
Covesion, the company spun out of the University of Southampton's research into materials for use in high-powered lasers, has grown into a multi-million pound business that has created high-technology jobs, attracted more than £1 million in US investment and won UK export orders around the world. Covesion's nonlinear crystals are used by the world's leading companies and research institutes in cutting edge applications that include fibre lasers, medical imaging, aircraft anti-missile defences, display projectors and the remote sensing of airborne hazardous materials. The global value of Covesion-enabled operations since the company's inception in 2009 is estimated to be in excess of US$100 million.
Impact: Economic gains
PHYESTA research has led to the setting up of a company now known as ForthDD. Since 2008 it has increased its annual revenue by more than 25% to around US $5M, and its global workforce from 25 to 35. It has released new products directly underpinned by PHYESTA research as recently as October 2012.
Significance:
A consortium involving PHYESTA staff in collaboration with Edinburgh's School of Engineering and five industrial partners realised the world's first high-resolution ferroelectric liquid crystal over silicon (FLCOS) microdisplay. This digital display attracted investment from the UK, Taiwan, and USA of over $40m, and was taken forward to production by MicroPix, MicroVue, and Forth Dimension Displays.
ForthDD now has offices in Valencia, USA, and Berlin, Germany. The company designs, develops and manufactures single chip microdisplays used in the demanding near to eye (NTE) training and simulation systems, HD video camera viewfinders, medical imaging systems and virtual reality and head-mounted displays.
ForthDD, its customers and business partners (e.g. in the medical imaging sector).
Attribution: This work was led within PHYESTA by Professor David Vass involving PHYESTA and done in collaboration with Edinburgh's School of Engineering.
Regulation of our sleep-wake cycle is crucial to health and well-being. The quality (intensity and spectral distribution) of artificial light is currently described according to its ability to activate rod and cone photoreceptors in the human eye. This approach ignores the discovery of a third photoreceptor that Lucas and his group have shown to be responsible for a range of sub-conscious neurophysiological and neurobehavioural responses to light, which together strongly contribute to health, productivity and well-being. Their research has established ways of measuring light that predict its effect on these newly discovered photoreceptors. They have partnered with industrial [text removed for publication] and public policy (various) organisations to translate this knowledge into improved artificial light sources and updated international standards for architectural lighting, for use in a wide range of domestic, public and industrial settings.