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Research in the laser photonics area has led to the formation and continuing development of two spin-out companies, Lynton Lasers Ltd and Laser Quantum Ltd, with annual turnover of £5.3m and >£12m respectively, and direct economic impact of [text removed for publication] over the REF period. Laser Quantum Ltd manufacture and market OEM diode pumped solid state lasers and Ti:sapphire lasers, which are incorporated in the products of major international companies in the scientific and entertainment sectors. Lynton Lasers Ltd manufacture and market medical devices for the cosmetic and aesthetic surgery market. Their products and services have underpinned the business of [text removed for publication] over the REF period. With an average cost of between [text removed for publication] over the REF period.
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.
Pound-Drever-Hall (PDH) locking, developed into a practical technique by researchers at the University of Glasgow, is the ubiquitous method for the precise frequency control of stable laser systems. This control is central to laser products from companies such as Toptica and Newport, and has an estimated global annual market in excess of £5M. The PDH stabilisation technique is essential for the operation of the time standards maintained in all of the world's Governmental Metrological Standards Laboratories (e.g. NPL, NIST, BIPM) and finds applications in inspection tools in the semiconductor industry and deep UV lasers for UV-Raman spectroscopy.
Impact: Economic Based on research carried out within PHYESTA, a range of novel laser devices have been produced and sold under licence by M Squared Lasers Ltd Glasgow.
Significance: The products have significantly expanded the M Squared product range and have led to increased sales and new customer relationships.
Reach: M-Squared have marketed these lasers worldwide and has had major sales from customers in the defence and oil and gas sectors. New collaborations have been enabled with international partners including the Fraunhofer Centre for Applied Photonics (Glasgow).
Beneficiaries: M-Squared Lasers
Attribution: The devices were developed by PHYESTA Researcher Professor Malcolm Dunn's research group
Midaz Lasers Ltd is a spin-out laser company formed by academic founders, Professor Michael Damzen (Director and Chief Technology Officer, CTO) and Dr Ara Minassian (Chief Scientific Officer, CSO), in 2006 as the vehicle for commercial exploitation of patented laser technology [4] arising from Prof Damzen's research group in the Physics Department at Imperial College London.
Midaz has designed and assembled multiple engineered laser and amplifier products, incorporating this patented technology, and has sold units to industrial customers in Europe, N. America and Asia since 2010. The primary market and beneficiary for Midaz laser technology is the industrial laser manufacturing sector and the benefit of the technology is to create laser industrial tools for higher throughput and lower cost manufacturing, including in the semiconductor industry for production of consumer electronics. In July 2012, Midaz was successfully sold to world-leading laser company, Coherent Lasers Ltd, for $3.8 Million.
Commercialisation of high optical quality diamond by Element Six Ltd (2010 on) and of diamond- enabled lasers by M Squared Lasers Ltd (2012 on) has been made possible by underpinning research on laser engineering and optical characterisation at the University of Strathclyde. [text removed for publication] Markets for this material include thermal management of lasers to enable higher powers and high-performance laser output windows. [text removed for publication]
Research at the University of Manchester on laser cleaning of Ti alloys has resulted in practical implementation of the technology at Rolls-Royce for the automatic preparation of surfaces prior to electron beam welding. This has been applied to 24 different aero-engine component types including compressor drums across most current engine families. This has resulted in close to 100% `first time right' aero-engine component welds. The technology is also being adopted by BAE Systems to replace chemical cleaning during airframe manufacture. The elimination of manual and chemical cleaning processes results in savings of several million pounds per annum.
Research in solid state lasers and non-linear optics in the Department of Physics has led to the creation of innovative laser companies in Glasgow serving global scientific and industrial markets. World-leading products have opened up applications in biomedical imaging, security, defence, pollution monitoring, material processing and fundamental spectroscopy. The companies Coherent Scotland Ltd and M Squared Lasers Ltd can trace a direct link to the research in the Department of Physics and are the central theme of this case study. Since 2008, these two companies have created an estimated 600 person years of employment and £135M of sales from products underpinned by research undertaken at Strathclyde. The wider cluster of companies, researching, designing and developing laser products, including Thales Optronics and more recently the Fraunhofer Centre for Applied Photonics, which has a close working relationship with the University, has made Glasgow one of the leading European centres for innovative laser manufacture.
High-power lasers developed at the University of Glasgow now lie at the heart of state-of-the-art technologies in the commercial printing, medical and defence markets. University of Glasgow spin-out company Intense has introduced more than 10 new diode laser products with superior brightness, longer lifetimes and increased reliability to these markets since 2008. [text removed for publication.] In 2011 Intense was bought by ORIX USA Corporate Finance Group for an undisclosed sum.
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.