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The development of a high average power, all-fibre integrated, supercontinuum (or "white light") source, has led to a completely new product that has had significant commercial impact on the fibre laser and applications market place. The basic science, the technologically important power scaling and all-fibre integration were undertaken and first demonstrated by Imperial College staff. This device is currently sold as a compact free standing device by companies such as Fianium, NKT Photonics and IPG Photonics. Sales of supercontinuum lasers at Fianium alone have greatly exceeded £10M. The device has also been successfully incorporated into spectroscopic and medical imaging instrumentation generating new business activity through this disruptive technological change.
High power fibre laser research undertaken at the University of Southampton has led to the creation of a new business sector in the generation of highly efficient and highly practical fibre laser technology. This has revolutionised areas of industrial material processing and enabled the development of specialist components for high-end industries (such as aviation and defence) as well as an array of new medical devices, procedures and manufacturing technologies. The research is also directly responsible for the commercial success and sustained growth of a spin-out company, SPI Lasers Ltd, which has an annual turnover of over £40 million and employs more than 250 people in the Southampton area.
Researchers at the University of Southampton were the first in the world to introduce ytterbium-doped silica fibre as an optical gain medium. The work led to the creation of a new business sector around efficient industrial fibre lasers, which enable new manufacturing processes in the automotive, aviation, defence and medical device industries, with a reduction in carbon footprint relative to earlier technologies. The economic impact of this work includes the UK foothold in the $2 billion global industrial laser market through the success of two spin out companies — Fianium and SPI Lasers — with a combined turnover of £50 million, employing close to 300 people
Research by Bath physicists into non-linear effects in optical fibres has led directly to the development of a new technology: bright white light ("supercontinuum") lasers which remove the need for multiple single wavelength laser systems in low power applications. Based on a successful collaboration with Bath, these lasers are marketed by Fianium Ltd (est. 2003). Since 2008 Fianium has expanded greatly [text removed for publication]. In recognition of this success, Fianium received the Queen's Award for Enterprise in both 2009 and 2012. Bath physicists and Fianium continue to engage in knowledge exchange projects which has resulted in over £1M of DTI/TSB investment funding, [text removed for publication].
Ultra-precise Bragg grating writing-technology, invented in the Optoelectronics Research Centre (ORC), has led to impacts in the areas of security, safety, detection of bio-hazards and the underpinning laser technology currently being pursued for clean energy generation for future energy security. This case study highlights two aspects of the technology namely: planar-based for optical microchip sensors in areas such as portable detection of biohazards, which has resulted in the spin-out Stratophase, and fibre-based, inside the US National Ignition Facility (NIF), the world's largest laser system, based in California, built for fusion-energy research, which has ORC fabricated fibre Bragg gratings within its laser amplifier chains. These ultra-high precision laser-written engineered gratings have enabled important advances in biosecurity, management of environmental hazards and clean energy research.
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.
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.
Impact: Economic gains / altered business practices.
Research on ultrafast lasers has led to the development of new products and services and has been pivotal in the development of a whole field of new technology.
Significance: The research underpins the product development of a range of world leading companies including Femtolasers, Newport Spectra-Physics and Menlo Systems.
Reach: The companies that use the technology represent all of the leading players in the solid-state femtosecond laser field, a marketplace worth more than $250M annually.
Beneficiaries: The impact presents economic gains to the companies involved and underlies many applications in e.g. biology and medicine, providing significant benefits to the public at large.
Attribution: The research was performed by Professor Sibbett's group.
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.
This research has led to the creation of new business sectors in laser development for medical and healthcare applications, which has enabled the creation of a world-wide market worth US$96 million in 2011, and a local spin-out, Fianium Ltd, which now has more than 50 employees and an annual turnover of around £10 million. Exploiting a radically new optical component invented at the University of Southampton, the microstructured optical fibre (MOF), this research has led to economic benefit through the creation of hundreds of jobs worldwide, and enabled the development of new diagnostic and medical technologies.