Early history

High-power laser research began at Imperial from 1962 with the aim of developing a home-built ruby system by Mike Key (later Director of CLF) as part of his PhD project in the Plasma Physics Group, following a conversation over coffee with Malcolm Haines, then a young lecturer. After three years of development the system was linked to a small theta pinch in 1965 for Thompson scattering experiments^[Reference Key^35] to diagnose magnetized plasma conditions. Dan Bradley also joined Imperial at this time as a lecturer in the Instrument Technology Group (J. D. McGee’s group, later named Applied Physics). He began to collaborate with UKAEA Culham, who had one of the first commercial ruby lasers in the country: the Triton Instruments LS-4, which was a Q-switched system, which Dan used for work related to scanning Fabry–Pérot and image tubes (both for storage and image enhancement). Dan and Mike left Imperial in 1964 along with the ruby laser system (later retrofitted with Nd:glass), moving first to Holloway where Dan was appointed Reader, and then on to QUB where Mike was appointed to a lectureship and Dan took up a chair in 1966, with only the development of a home built HeNe laser and a pulsed CO₂ system for probing plasmas continuing at Imperial.

PhD student Malcolm White along with Bucker Dangor (one of the founders of the field of laser particle acceleration) built a megawatt class CO₂ system comprising an oscillator and three amplifiers (with parts from the local ‘corner store’ Harrods)^[Reference White and Dangor^36]. This system was used to make the first ever experimental measurement of the thermal conductivity in a laser heated plasma and compare it with the theoretical prediction^[Reference White, Kilkenny and Dangor^37]. Bucker also built a HeNe laser in 1964/1965 based on a system designed and built by the Baldock research laboratory associated with the Royal Navy before systems of this type became commercially available, using a laser tube blown by Oscar, the resident physics glass technician.

The pace accelerated markedly when Dan Bradley returned to Imperial in 1973, taking up a chair in laser physics, and bringing with him a vibrant group of staff, postdocs and PhD students including Geoff New (a future head of the Laser Optics and Spectroscopy (LASP) Group), Henry Hutchinson (later Director of the Blackett Laser Consortium and then the CLF at RAL), Roy Taylor, Paul Ewart and Wilson Sibbett. Roy and Wilson have since been appointed Fellows of the Royal Society, highlighting what an extraordinary team Dan Bradley was building at this time. Other individuals such as Bill Toner and Alan Cairns were involved in Dan’s team with theoretical support from Geoff New (one of the pioneers of the OPCPA technique), and Malcolm Haines who was to become Head of Plasma Physics at Imperial and one of the UK’s most prominent theoretical plasma physicists. Dan Bradley was Head of the Physics Department at Imperial from 1976 to 1980.

In the early 1970s Dan Bradley and Malcolm Haines played a key role in establishing the CLF at RAL. Members of the Plasma Physics Group such as Joe Kilkenny were early users of the new Nd:glass system at RAL, which was later named VULCAN.

Dan and his team continued to work on passively, actively and hybridly mode-locked continuous wave (CW) dye lasers, with the former delivering the first reliable source of pulses of a few hundred femtoseconds^[Reference Ruddock and Bradley^38]. At various times throughout the 1970s Dan’s group held the record for the shortest pulses generated by a laser. They also linked lasers to innovative electro-optic systems such as streak cameras, developing the synchroscan streak camera^[Reference Adams, Sibbett and Bradley^39], which was to revolutionize real-time, ultra-fast diagnostics. This was coupled to a what was for its time a substantial 100 mJ, 5 ps Nd:silicate picosecond pulse seeded chain with four amplifier stages. This allowed for the characterization of VUV streak cameras using the sixth and tenth harmonics (i.e., third and fifth harmonics of the second harmonic in neon or xenon). The shortest harmonic generated was the 28th order (the 7th order of the 4th harmonic) in a system shown in Figure 5. Work to extend streak camera operation into the soft and hard X-ray ranges for use in laser fusion research^[Reference Stradling, Studebaker, Cavailler, Launspach and Planes^40] was also conducted in the Plasma Group with Joe Kilkenny, Jonathan Hares and Anthony Dymoke-Bradshaw developing systems which were then commercialized very effectively by Kentech Instruments^[41].

Figure 5

An early ~100 mJ, 5 ps flashlamp-pumped Nd silicate glass laser built by Roy Taylor at Imperial to investigate high harmonic generation (HHG; 2nd, 4th, 28th in Ne or He). (Picture courtesy of Imperial College London.)

Gigawatt pulsed dye laser systems operating at the few millijoule, few picosecond level^[Reference Adrain, Arthurs, Bradley, Roddie and Taylor^42] were also developed by Roy Taylor, with a flashlamp pumped dye laser system in 1974 (R6G/RB mode locked with DODCI/DQOCI (3,3’-diethyloxadicarbocyanine iodide/1,3’-diethyl-4,2-quinolyloxacarbocyanine iodide)) driving third and fifth harmonics and four wave mixing in alkali vapours and inert gases for tunable VUV generation, along with an expanding research programme in increasingly larger and larger aperture e-beam pumped excimer gas lasers for VUV generation^[Reference Bradley, Hull, Hutchinson and McGeoch^43]. An early excimer laser developed by the group is shown in Figure 6.

Theoretical work also continued, with Bradley and New publishing a seminal invited review paper of the field^[Reference Bradley and New^44], the first work to give a comprehensive coverage to the physics of short pulse measurement. Geoff New went on to become a leading theoretician in the field of non-linear optics modelling a number of experiments within the Sprite and TITANIA programmes at RAL and with Ian Ross and others at RAL, developing the theoretical underpinnings of the OPCPA technique now employed by many high-power systems worldwide^[Reference Ross, Matousek, New and Osvay^45]. In parallel with laser development work at Imperial, members of the then Spectroscopy Group including Dave Burgess and Anne Thorne saw the potential of lasers as powerful probes of excited states and began to exploit lasers for experiments in plasma spectroscopy from the early 1970s onwards^[Reference Burgess and Skinner^46]. Other members of the Spectroscopy Group at the time included Hans Bachor and Ken Baldwin, later leaders of laser development in Australia along with Jinx Cooper who went on to leadership roles at JILA in Colorado.

Figure 6

Dan Bradley and Henry Hutchinson’s excimer laser in the basement of the Huxley building, Imperial College London. (Picture courtesy of Imperial College London.)

In the early 1980s members of the Plasma Physics Group became major users of the UK’s high-power laser facilities at the CLF. For example, Oswald Willi and his team, investigated early X-ray laser schemes, detailed later in the section on the X-ray Laser Consortium. Oswald’s team also worked on plasma instabilities and thermal transport^[Reference Willi, Kiehn, Edwards, Barrow, Smith, Wark and Turcu^47] related to laser fusion and in 1989 led the first interaction experiments using the Sprite laser at RAL. Sprite was also used to test ideas for creating ‘low-temperature’ laser plasmas that could be used for recombination X-ray laser schemes by Bucker Dangor in collaboration with Mike Key and Justin Wark^[Reference Offenberger, Blyth, Dangor, Djaoui, Key, Najmudin and Wark^48]. A large cohort of PhD students were also trained by Oswald, Bucker and others at this time, with many moving on to prominent roles elsewhere, for example John Edwards (associate director for inertial confinement fusion at NIF), Mike Dunne (Director of LCLS) and Marco Borghesi (Professor and Head of Group at QUB).

Work led by Bucker Dangor at this time also sought to use the VULCAN laser as a driver for an electron acceleration scheme using a ‘beat-wave’. This required co-propagating two synchronized and slightly different wavelength pulses through VULCAN, a major technical challenge at the time given the inherent bandwidth limitations of Nd:glass. The CLF adapted the 100 ps oscillator system on VULCAN, led by Colin Danson, to produce two wavelengths 1053 and 1064 nm in Nd:YLF and Nd:YAG and then used a mix of Nd:phosphate and silicate glass in the amplifier chain to give high-energy synchronized pulses at both wavelengths^[Reference Dangor, Afshar-Rad, Cole, Danson, Dymoke-Bradshaw, Dyson, Edwards, Evans, Garvey and Mitchell^49]. However, the beat-wave acceleration scheme itself was extremely challenging to operate as it required exquisite matching between the laser and plasma conditions and was eventually superseded by single-pulse techniques.

Blackett Laboratory Laser Consortium (BLLC) and early CPA lasers in the UK

With the first demonstration of the elegant CPA technique to circumvent non-linear optical damage in a high-power laser in 1985 by Strickland and Mourou^[Reference Strickland and Mourou^50] it became clear that there were important opportunities to extend high-power laser science and exploit this new technique in areas including high-field atomic physics and laser plasma experiments. A collaboration between leading theoretical and experimental physicists from the LASP and Plasma Physics Groups at Imperial led by Peter Knight, Henry Hutchinson, Keith Burnett, Oswald Willi, Dave Burgess and J.-P. Connerade with then Postdocs Roland Smith and Jon Marangos set out to develop a Nd:glass-based 1 J, 1 ps table-top terawatt (T³) laser at Imperial. This system initially used a 10 ps actively mode-locked Nd:YLF oscillator, pulse stretching and bandwidth generation in 2 km of optical fibre and then regenerative and multi-pass amplification in Nd:glass. It was the first CPA laser of its kind operational in Europe and is shown in Figure 7. Early successes driven by this system focused on high harmonic generation (HHG) and included the first temporal^[Reference Faldon, Hutchinson, Marangos, Muffet, Smith, Tisch and Wahlstrom^51], spatial^[Reference Tisch, Smith, Ciarroca, Muffet, Marangos and Hutchinson^52] and coherence measurements^[Reference Ditmire, Gumbrell, Smith, Tisch, Meyerhofer and Hutchinson^53] of high-order harmonics, work that now underpins the field of attoscience.

Figure 7

The UK’s first table-top terawatt (TReference Gould³) system, a 1 J, 1 ps TReference Gould³ laser developed at Imperial College by the Laser Consortium, circa 1998. This was the first operational T³ CPA laser system in Europe, built by PhD student Mary Falden and then Postdoc Roland Smith. (Picture courtesy of Imperial College London.)

The T³ system operated for over a decade, being upgraded a number of times to shorter-pulse and higher-energy operation by Roland Smith, with larger gold holographic compressor gratings and a Martinez-style stretcher in place of the original optical fibre. It was then used for much of the formative work on high-intensity laser interactions with atomic clusters^[Reference Ditmire, Smith, Tisch and Hutchinson^54, Reference Ditmire, Smith, Marjoribanks, Kulcsar and Hutchinson^55] key aspects of which were driven by then Postdoc Todd Ditmire (now Professor at University of Austin at Texas), EPSRC Research Fellow John Tisch (now Professor and Head of the QOLS Group at Imperial) and Roland Smith. This work exploited the unique ability of clusters to couple to intense few picoseconds laser pulses through a dynamic plasma resonance^[Reference Ditmire, Smith, Tisch and Hutchinson^54, Reference Ditmire, Tisch, Springate, Mason, Hay, Marangos, Smith and Hutchinson^56, Reference Springate, Hay, Tisch, Mason, Ditmire, Hutchinson and Marangos^57] and was fundamental in launching the field of laser–cluster interaction physics, which led to later successes such as a demonstration of table-top thermonuclear fusion at LLNL using the Falcon laser^[Reference Zweiback, Smith, Cowan, Hays, Wharton, Yanovsky and Ditmire^58] in collaboration with scientists from Imperial.

The Blackett Laboratory Laser Consortium (BLLC), funded by grants from ESPRC, MoD and Imperial College, was initially under the directorship of Henry Hutchinson, and later Jon Marangos after Henry moved to RAL as the director of CLF. Techniques and diagnostics developed on the original Nd:glass CPA laser (for example, high-dynamic-range third-order autocorrelation^[Reference Luan, Hutchinson, Smith, Zhou and Meas^59] and fibre-mode locked oscillators for use as the front end of a picosecond CPA laser^[Reference Mercer, Chang, Danson, Edward, Hutchinson and Miller^60]) were instrumental in helping the CLF and other laboratories in Europe implement the CPA technique more effectively on larger-scale systems such as VULCAN. Imperial also collaborated with the CLF on the first CPA target experiments at RAL which observed plasma and MeV particle jet collimation^[Reference Bell, Beg, Chang, Dangor, Danson, Edwards, Fews, Hutchinson, Luan, Lee, Norreys, Smith, Taday and Zhou^61]. The higher energies and higher intensities produced by VULCAN enabled a series of high-profile collaborative experiments led by Imperial’s Bucker Dangor, including the first demonstration of self-injection from wakefield accelerators^[Reference Modena, Najmudin, Dangor, Clayton, Marsh, Joshi, Malka, Darrow, Danson, Neely and Walsh^62], the production of energetic jets of protons and heavy ions^[Reference Clark, Krushelnick, Davies, Zepf, Tatarakis, Beg, Machacek, Norreys, Santala, Watts and Dangor^63, Reference Clark, Krushelnick, Zepf, Beg, Tatarakis, Machacek, Santala, Watts, Norreys and Dangor^64] and the production of solid harmonics up to the XUV^[Reference Norreys, Zepf, Moustaizis, Fews, Zhang, Lee, Bakarezos, Danson, Dyson, Gibbon, Loukakos, Neely, Walsh, Wark and Dangor^22].

The glass laser at Imperial also helped other groups establish their own high-power laser activities. Claes-Göran Wahlström who became Director of the Lund Laser Centre, Sweden, spent a year at Imperial working on the glass system before Lund began work on its own CPA program, while Simon Hooker, now Professor at Oxford, was able to conduct some of his first laser guiding experiments on this system at Imperial^[Reference Hooker, Spence and Smith^65].

The BLLC also worked on shorter-pulse high-power systems, initially on sub-100 fs colliding pulse mode locked dye lasers operating in the visible seeding an amplifier chain pumped with excimers during the early 1990s, while Roy Taylor and colleagues continued to make pioneering advances in ultra-fast seed sources, including the first self-mode locking of Ti:sapphire below 50 fs^[Reference Rizvi, French and Taylor^66]. However, the difficulty of scaling dye laser systems to high energy and the general hazards of working with toxic chemicals and flammable solvents prompted development of a high-energy Ti:sapphire system from the mid-1990s onwards. A 150 fs, 150 mJ Ti:sapphire CPA laser system was developed by a team including Mike Mason (now Director of Engineering, Coherent UK) and John Tisch, shown in Figure 8, and used as a platform for an extensive series of investigations into processes such as energetic cluster explosions^[Reference Shao, Ditmire, Tisch, Springate, Marangos and Hutchinson^67], HHG with molecular gases^[Reference Fraser, Hutchinson, Marangos, Shao, Tisch and Castillejo^68], high-field interactions with fullerenes^[Reference Hay, Springate, Mason, Tisch, Castillejo and Marangos^69] and pioneered experimental techniques that permit the study of strong field interactions with controllably aligned molecules^[Reference Velotta, Hay, Mason, Castillejo and Marangos^70]. Alongside these technical and scientific developments, the BLLC also trained a large cohort of PhD students, many of whom moved on to roles in industry and both UK and international laboratories.

Figure 8

Imperial College’s terawatt 150 fs, 150 mJ Ti:sapphire CPA system circa 2000 being adjusted by the then PhD student Mike Mason. (Picture courtesy of Imperial College London.)

In the last decade, under Jon Marangos’ direction, the focus of the BLLC moved to the problem of generating and harnessing attosecond light pulses for probing ultra-fast processes such as electron dynamics and ionization in a single molecule. By this time, Ti:sapphire lasers operating at kilohertz repetition rates and tens of millijoules energies below 30 fs had become a commercial reality and the BLLC exploited a number of these systems as the front-end for innovative hollow-fibre bandwidth generation and pulse compression (HFPC) systems with much of the development led by John Tisch (now Professor and Head of the QOLS Group at Imperial). These hybrid systems were able to routinely deliver multi-millijoule pulses with world-leading durations below 4 fs^[Reference Witting, Frank, Arrell, Okell, Marangos and Tisch^71] and then drive sub-200 as soft X-ray pulses for experiments in surface science^[Reference Okell, Witting, Fabris, Arrell, Hengster, Ibrahimkutty, Seiler, Barthelmess, Stankov, Lei, Sonnefraud, Rahmani, Uphues, Maier, Marangos and Tisch^72], ultra-fast molecular rearrangement^[Reference Baker, Robinson, Haworth, Teng, Smith, Chirila, Lein, Tisch and Marangos^73] and molecular dynamics^[Reference Torres, Siegel, Brugnera, Procino, Underwood, Altucci, Velotta, Springate, Froud, Turcu, Patchkovskii, Ivanov, Smirnova and Marangos^74]. The BLLC became the primary centre for attoscience in the UK, but the tradition of spinning out core expertise and technologies to UK national laboratories continued, with an Imperial HFPC system being installed at RAL to enable the Astra Artemis system to deliver sub-femtosecond pulses for use by the wider scientific community.

Work also continued on higher-energy in-house systems, with the development of Cerberus, a large multi-beam OPCPA/Nd:glass laser by a collaboration between the QOLS and Plasma Physics groups led by Roland Smith and Sergey Lebedev. Construction of Cerberus began in 2008, and a unique feature of this system and its initial scientific driver was the ability to deliver light to both standalone target areas and the megaamp, megavolt Z-Pinch MAGPIE allowing it to drive fully quantitative plasma diagnostics including two-dimensional Faraday rotation imaging of magnetic fields^[Reference Swadling, Lebedev, Hall, Patankar, Stewart, Smith, Harvey-Thompson, Burdiak, de Grouchy, Skidmore, Suttle, Suzuki-Vidal, Bland, Kwek, Pickworth, Bennett, Hare, Rozmus and Yuan^75] and multi-point Thomson scattering^[Reference Harvey-Thompson, Lebedev, Patankar, Bland, Burdiak, Chittenden, Colaitis, De Grouchy, Doyle, Hall, Khoory, Hohenberger, Pickworth, Suzuki-Vidal, Smith, Skidmore, Suttle and Swadling^76]. This capability is currently only rivalled by the much larger Z-Beamlet and Z-Facility at the Sandia National Laboratory, USA. Cerberus includes a number of 50 mm diameter Nd:glass rod amplifiers donated by AWE following the shutdown of the HELEN laser, allowing long-pulse operation at energies beyond ~30 J. The short pulse arm is currently limited to ~5 J, 500 fs, 10 TW operation as a result of B-integral in the compressor, however in 2021 a new vacuum compressor and a series of additional larger aperture OPA gain stages will be commissioned, which will allow Cerberus to deliver >20 J, 50 TW shots on target.

The front-end architecture of Cerberus is by a combination of design and ‘convergent evolution’ very similar to that of the Orion laser at AWE, allowing this system to be used for proof of principle laser and diagnostic development for Orion. It has also been used to develop new plasma diagnostic systems such as multi-wavelength imaging interferometry^[Reference Patankar, Gumbrell, Robinson, Lowe, Giltrap, Price, Stuart, Kemshall, Fyrth, Luis, Skidmore and Smith^77] and high-brightness broad-band light sources^[Reference Floyd, Gumbrell, Fyrth, Luis, Skidmore, Patankar, Giltrap and Smith^78] for Orion, a facility also accessed by members of the Plasma Physics Group for experiments in areas such as radiative astrophysical shock studies^[Reference Suzuki-Vidal, Clayson, Stehlé, Swadling, Foster, Skidmore, Graham, Burdiak, Lebedev, Chaulagain, Singh, Gumbrell, Patankar, Spindloe, Larour, Kozlova, Rodriguez, Gil, Espinosa, Velarde and Danson^79].

The strong Iλ ² scaling of ponderomotive energy with laser wavelength, and the success of >1.5 μm lasers in driving HHG to shorter wavelengths highlighted the attraction of mid-IR laser systems for extreme optical physics. In 2016 Imperial began work on a new high-energy mid-IR laser Chimera co-funded by Defence and Science Technology Laboratory (DSTL), EPSRC and the US Air Force Office of Scientific Research (AFOSR) as part of the first of a series of multi-national UK–US MURI projects. Chimera is a multi-beam mid-IR laser with an 800 nm, 7 fs Ti:sapphire front end, seeding a high-energy Nd:YLF pump chain, an 800 nm OPCPA stage which then generates 2–4.5 μm light by difference frequency generation with over 1 μm of bandwidth. A series of OPA gain stages then amplify 3.7 and 1.6 μm pulses, with a target performance of >50 mJ, 30 fs at 3.7 μm and higher energies at 1.6 μm. The system is currently operational at ~7 mJ and being scaled up towards its final target energy. The MURI project also funds mid-IR laser development and its exploitation for ultra-fast science^[Reference Johnson, Austin, Wood, Brahms, Gregory, Holzner, Jarosch, Larsen, Parker, Strüber, Ye, Tisch and Marangos^80, Reference Johnson, Miseikis, Wood, Austin, Brahms, Jarosch, Struber, Ye and Marangos^81] by extending the wavelength shifting and HFPC capabilities of lower energy, but higher repetition rate kilohertz systems operated by the Extreme Light Consortium.

Scientists from Imperial continue to be highly active at RAL and Orion in the UK and at other leading laser facilities worldwide, with for example Stuart Mangles and Zulfikar Najmudin leading prominent activities in gigaelectronvolt electron acceleration^[Reference Mangles, Murphy, Najmudin, Thomas, Collier, Dangor, Divall, Foster, Gallacher, Hooker, Jaroszynski, Langley, Mori, Norreys, Tsung, Viskup, Walton and Krushelnick^82, Reference Kneip, Nagel, Martins, Mangles, Bellei, Chekhlov, Clarke, Delerue, Divall, Doucas, Ertel, Fiuza, Fonseca, Foster, Hawkes, Hooker, Krushelnick, Mori, Palmer, Phuoc, Rajeev, Schreiber, Streeter, Urner, Vieira, Silva and Najmudin^83], multi-megaelectronvolt ion acceleration^[Reference Palmer, Dover, Pogorelsky, Babzien, Dudnikova, Ispiriyan, Polyanskiy, Schreiber, Shkolnikov, Yakimenko and Najmudin^84, Reference Willingale, Mangles, Nilson, Clarke, Dangor, Kaluza, Karsch, Lancaster, Mori, Najmudin, Schreiber, Thomas, Wei and Krushelnick^85] and betatron radiation imaging experiments^[Reference Kneip, McGuffey, Martins, Martins, Bellei, Chvykov, Dollar, Fonseca, Huntington, Kalintchenko, Maksimchuk, Mangles, Matsuoka, Nagel, Palmer, Schreiber, Phuoc, Thomas, Yanovsky, Silva, Krushelnick and Najmudin^86, Reference Cole, Symes, Lopes, Wood, Poder, Alatabi, Botchway, Foster, Gratton, Johnson, Kamperidis, Kononenko, De Lazzari, Palmer, Rusby, Sanderson, Sandholzer, Sarri, Szoke-Kovacs, Teboul, Thompson, Warwick, Westerberg, Hill, Norris, Mangles and Najmudin^87] at large facilities. During his time as Director of the CLF, Henry Hutchinson initiated the development of the Astra laser at the RAL. Astra was then used in the first demonstration of monoenergetic electron beams from a laser accelerator^[Reference Johnson, Austin, Wood, Brahms, Gregory, Holzner, Jarosch, Larsen, Parker, Strüber, Ye, Tisch and Marangos^80], by a team led by Krushelnick, Dangor and Najmudin. Astra and its successor Astra Gemini have continued to drive major advances in the field of laser-driven plasma accelerators, many of these proposed and lead by Imperial academics. To support their work at national facilities, the Plasma Group operates a home-built >100 mJ, 30 fs Ti:sapphire laser for small-scale acceleration experiments and diagnostic development, complementing Cerberus, Chimera and three ultra-fast laser systems operated by the Extreme Light Consortium, an evolution of the original BLLC.

Optical fibre development for communications

In 1966, work on optical fibres began at Southampton to try to make long-distance light communication a practical reality. In early days of fibre lasers in the ORC an agreement was made to parcel out the work on various rare earths so that ORC staff did not end up competing amongst themselves. In this arrangement Anne Tropper and Dave Hanna chose to work together on Yb and Tm, on the general basis that Yb seemed to offer virgin territory, having been generally neglected hitherto as a bulk laser candidate, on account of its three-level character (which was of less relevance in a fibre laser). Another attractive feature was the fact that Yb had a very simple energy level structure, thus presenting an ideal system for careful examination of basic principles. Tm was chosen for its opposite quality of having rather crowded energy levels and therefore a degree of complexity that could have room for surprises. These choices were not disappointing and the first operations of an Yb fibre laser^[Reference Hanna, Percival, Perry, Smart, Suni, Townsend and Tropper^112], and of a Tm fibre laser^[Reference Hanna, Percival, Perry, Smart, Suni, Townsend and Tropper^113], were achieved by Tropper, Hanna and colleagues in 1988. This was followed up with various examinations of their laser performance and prospects, which clearly indicated future promise for high-power performance. Indeed, this is now well-established and ongoing work under Dave Payne at the ORC, and elsewhere, has led to greatly increased power levels.

Fibre research led by Alec Gambling with David Payne as his research student resulted in the development of extensive fibre manufacturing capabilities allowing them to create fibres with losses of just 1000 dB/km. At the time, this was an amazing result, but more was to come. Although some of the pioneering communications laboratories across the world had dismissed silica optical fibres as impractical, losses had been reduced to a few decibels per kilometre^[Reference Luther-Davies, Payne and Gambling^114, Reference Payne and Gambling^115]. The development of specialized low-loss fibres using lower dopant levels was able to exploit longer interaction lengths^[Reference Poole, Payne and Fermann^116]. Another key piece to the puzzle was the invention of the first practical fibre optical amplifier to boost the intensity of light signals^[Reference Mears, Reekie, Jauncey and Payne^117]. This made long-distance optical communications practical, as many signals could be easily sent hundreds of miles without requiring electronic conversion. The effect was to make huge amounts of bandwidth available at low cost over very long distances. This was a major pre-requisite for the formation of the Internet as it is today. David Payne, shown in Figure 14, was elected as a Fellow of the Royal Society in 1992^[118] and knighted in the 2013 New Year Honours for services to photonics research and applications.

Figure 14

Sir David Payne conducting research on optical fibres. (Picture courtesy of the University of Southampton.)

David’s research in this field has also led to the development of high-power lasers based on specialized optical fibres. These fibre lasers were ‘born’ out of research at Southampton’s ORC and have led to the development of highly efficient and highly practical fibre laser technology. In the 1990s the researchers explored the testing and identification of the critical rare earth ion dopants (ytterbium, erbium and thulium) and the core glass compositions required to generate and reliably sustain ultrahigh levels at near-IR wavelengths.

They developed large-mode-area core designs capable of handling high powers and high pulse energies. This key research provided access to the multi-kilowatt class, high brightness laser regime and was critical in the success of the spin-out company SPI Lasers UK Ltd^[119]. SPI started out as a ‘telecomms’ company, not a high-power laser company at all. In the big telecomms recession most such start-ups died, but SPI reinvented itself successfully as a high-power fibre laser company. Southampton’s high-power fibre laser research has revolutionized areas of industrial material processing and enabled the development of specialist components for high-end industries such as aviation and defence. It has also been significant in the creation of an array of new medical devices, procedures and manufacturing technologies.

The ORC suffered a second major set-back in 2005 with another major fire. Following major rebuilding and reconstruction of facilities such as clean-rooms and fabrication suites, research has since forged ahead.

The Zepler Institute was established at the University of Southampton in 2013 and is the largest photonics and electronics institute in the UK. It has over 350 research staff and PhD students who use their expertise in optoelectronics, electronics, quantum technologies, physics and nanoscience to develop technologies and devices that tackle key societal challenges. It brings together leading researchers from across the University and enables innovation by providing access to one of the most comprehensive collections of nanoelectronics and photonics fabrication equipment in Europe. The institute has an interdisciplinary, industry-focused approach to research which has resulted in many successful spin-outs and the commercialization of products.

Laser–plasma interactions

Given Stuart Ramsden’s interests in laser-produced plasmas and thermonuclear fusion, the construction of solid-state lasers became an important departmental activity from the late 1960s onward. High-power Nd:glass and Nd:YAG devices were developed for laser–matter interaction studies, with Richard Dewhurst concentrating on picosecond and burst-mode laser oscillators for gas breakdown and plasma heating and Bob Hyde on developing laser amplifiers. In the 1980s Richard Dewhurst^[Reference Dewhurst, Al-Obaidi, Ramsden, Hadland and Harris^123] went on to exploit solid-state laser-generated plasmas for exciting high-frequency ultrasound waves in materials, applying this to a wide range of non-destructive testing techniques. He also developed novel laser-based sensing methods.

1970 saw the appointment of Dr. Geoffrey Pert who set up a Laser–Plasma Interaction Theory Group giving an important impetus to the high-power laser–plasma activity. He developed detailed computer models of the plasma physics involved (e.g., ionization mechanisms, fluid dynamics) in materials exposed at high laser irradiance. A key objective of this work became identifying and modelling systems in which a population inversion could be established in the XUV spectral region which was seen as a path to an ‘X-ray’ laser. In parallel with this, experimental work was implemented using a multi-joule sub-nanosecond Nd:laser oscillator–amplifier and target chamber with diagnostics to test numerical simulations. This was housed in the ‘Annex’, a room adjacent to the university sports centre.

Following initial work on planar geometries it was recognized that targets of reduced dimensionality, i.e., in fibre form, could produce the desired rapid plasma expansion needed for inversion. In 1980, using line focusing and micrometre scale-size carbon fibre targets, spectroscopic studies provided evidence of gain at 18.2 nm in the recombining carbon plasma^[Reference Jacoby, Pert, Ramsden, Shorrock and Tallents^124]. This was a major milestone in the development of XUV lasers. The group went on to make many further important contributions to understanding the dynamics and spectroscopy of plasmas for a variety of target systems.

A remote sensing group. The group investigating laser and non-linear optical techniques for LIDAR in atmospheric sensing and related theoretical studies was formed in the 1970s under Dr. Eric Thomas and Dr. Barry Rye. The central interest was coherent laser radar and its use in meteorological applications to measure properties such as wind velocity, temperature and relative humidity, as well as trace gas concentrations. The group developed tuneable IR systems based on narrow bandgap diode lasers and super-atmospheric pressure CO₂ lasers and also investigated sensitive signal detection methods such as optical heterodyning. The experimental work was complemented by comprehensive theoretical modelling of the atmosphere including turbulence, as well as modelling of the overall LIDAR system in terms of source and detector and signal/data processing requirements. Dr. Thomas (with Professor John Bryant in Physics) set up a spin-out company, Laser Monitoring Systems, to capitalize on some of the group’s research^[125].

Satellite laser ranging. In the late 1970s, a joint initiative of the Royal Greenwich Observatory (RGO) and Professor Stuart Ramsden was awarded SERC/NERC funding to develop and construct the UK Satellite Laser Ranging (SLR) Facility for Geodesy research at RGO, Herstmonceux, Sussex.

The Hull team, led by Denis Hall and including Bob Hyde and Don Whitehead with guidance from Stuart Ramsden, was charged with developing the overall system design and integration, as well as having prime responsibility for the laser transmitter, optical receiver sub-systems and the pulse transmit/receive timing system, all of which were initially assembled in Hull. These functions were subsequently integrated with other key system components including the main transmit/receive tracking optical telescope and finally assembled within a pre-existing telescope dome (The Solar Dome) located at RGO, Herstmonceux, shown in Figure 16. In addition, following interaction with the CAA, an X-band aircraft detection radar was assembled with a tracking antenna locked in pointing to the laser beam transmitting telescope. This configuration was used as the basis of a laser lock-out system to prevent eye damage to passengers in over-flying aircraft.

Figure 16

The Satellite Laser Ranging System at Herstmonceux with images of the Lageos Satellite and the SLR system in operation at night with the transmitted beam visible. (Picture courtesy of the University of Hull.)

The original system laser was a mode-locked Nd:YAG device producing frequency-doubled 532 nm, 100 ps, 10 mJ pulses at 10 Hz, and developed with high operational reliability by Clive Ireland and colleagues at Lumonics UK, Rugby. The first detected range data returned from the ‘co-operative’ NASA satellite Lageos (Laser Geodynamics Satellite) were achieved at night in early 1983, and daytime operation (in sunlight) was realized soon afterwards. Lageos is a 60 cm sphere covered with 426 corner-cube retroreflectors and is in a stable Earth orbit at an altitude of 5900 km. Range measurement accuracy of ~1 cm is achievable with appropriate calibrations.

Although in the intervening time, the RGO and most of its personnel and equipment have been relocated, the satellite laser ranging facility has remained in its original site, and the activities are managed as an NERC outstation: the Space Geodesy Facility (SGF). The system has seen a number of hardware upgrades over the intervening years, notably with the introduction of second (alternative) laser producing much shorter, higher-repetition-rate pulses (10 ps at 2 kHz) and an epoch timer allowing several trackable pulses to be in the air at once.

In addition, the UK SGF continues to play a significant role within the global geodesy community via the International GNSS Service networks, and as one of the eight Analysis Centres of the International Laser Ranging Service (ILRS).

Radiofrequency discharge excited CO₂ lasers. Research at Hull on the use of capacitive radiofrequency (RF) discharges to excite CO₂ waveguide lasers began with the arrival of Denis Hall at Applied Physics in mid-1979. With support from the MoD and the excellent departmental technical support in mechanical construction and RF electronics, early progress was quite rapid with the first experimental RF waveguide CO₂ laser device demonstrated at 5 W CW output before the end of the year.

The immediate research objective was to achieve sufficient understanding of the underlying RF laser device physics to enable the development of practical and compact lasers that could operate without the need for gas flow at power and brightness levels which facilitate their use in practical applications, for example, in manufacturing and surgery.

The work at Hull progressed with parallel activities in laser device technology and underpinning research in two key areas, RF discharge physics and the laser beam quality achievable with different RF discharge geometries. The first included studies of RF discharge stability conditions for different cross-sectional geometries (square, annular and planar rectangular) and varying axial lengths, plus the dependency of electron energy distribution and excitation rates on geometry, excitation frequency and gas pressure/mixture combinations all with the objective of optimizing laser power extraction and efficiency. Second, and in parallel, research was conducted on the optical properties of various resonator designs for RF lasers based on square, rectangular and annular (folded slab) cross-sectional gain media, and with dimensions appropriate for either waveguide or free space, intracavity optical propagation.

Under the leadership of Geoff Allcock and Ken Lipton (see Section 4), early commercialization of sealed-off CW RF lasers was achieved at the 50 W level in 1982 by Laser Applications Ltd (LAL), a spin-off company from the Applied Physics Department, thereby enabling the first commercially available laser medical system based on sealed CO₂ laser technology which was successfully marketed in Europe and the USA.

Subsequently over the next decade, physics understanding blossomed and world-ranking CO₂ laser performance was demonstrated in linear waveguide lasers^[Reference He and Hall^126], annular lasers^[Reference Xin and Hall^127], slab waveguide lasers^[Reference Jackson, Baker and Hall^128, Reference Colley, Baker and Hall^129], as well as phase-locked and unlocked waveguide laser arrays^[Reference Abramski, Colley, Baker and Hall^130, Reference Baker, Hornby and Hall^131] at multi-hundred-watt levels.

Planar waveguide lasers

Howard Baker and Denis Hall introduced the highly compatible combination of capacitive RF discharge excitation with planar waveguide gain medium structures and hybrid resonator designs to achieve highly compact and efficient sealed pulsed/CW CO₂ lasers at power levels to >1 kW^[Reference Jackson, Baker and Hall^128, Reference Abramski, Colley, Baker and Hall^144, Reference Colley, Baker and Hall^129], shown in Figure 18, and capable of high-repetition-rate ‘super-pulse‘ operation^[Reference Villarreal, Murray, Baker and Hall^145] for use in diverse material processing applications. This format was successfully applied to high-power CO and Xe lasers at Heriot-Watt University and commercialized for CO₂ lasers by Rofin-Sinar UK Ltd in Hull (see Section 4).

Figure 18

A 1 kW sealed RF planar waveguide CO₂ laser with Dr. Alan Colley and Dr. Suzy Zhang. (Picture courtesy of Heriot-Watt University.)

The same group also used planar waveguide gain medium structures to achieve powers of 150 W from Nd:YAG^[Reference Lee, Baker, Friel, Hilton and Hall^146] using close-linked diode array face-pumping of the thin slab waveguide, and over 400 W from Yb:YAG^[Reference Thomson, Monjardin, Baker and Hall^147]. In the latter case, efficient diode array side-pumping of the thin planar waveguide slab was achieved using a novel freeform optical coupling component to correct the imperfect diode array pointing. The freeform optical component was custom-designed and laser-fabricated within the group, using technology, an enhanced version of which was the basis of the manufacturing process developed and commercialized by the Heriot-Watt spin-off company, PowerPhotonic Ltd.

In addition, the wide bandwidth of the Yb:YAG laser later allowed this technology to enable the amplification of 1030 nm femtosecond pulses to many tens of watts^[Reference Leburn, Ramirez-Corral, Thomson, Hall, Baker and Reid^148], with relevance to high-throughput femtosecond laser machining.

The early years

Laser research at Strathclyde emerged from a group studying plasma physics as was the case with so many research groups around the UK as well as elsewhere. Bob Illingworth teamed up with Ivan Ruddock who moved to Strathclyde from Imperial College where he had been a student of Dan Bradley. Bob and Ivan worked on synchronously pumped dye lasers and colour centres lasers to produce ultra-short pulses. They were later joined by Geoff Duxbury who was one of the early adopters of laser spectroscopic techniques for the investigation of the IR spectra of molecular species.

The first professorial appointment in lasers at Strathclyde was Tony Smith in 1979. Tony had worked with Malcolm Dunn and Arthur Maitland at St Andrews and brought his expertise in plasmas to build a gas laser group predominantly working on TEA CO₂ lasers. Tony decided to move into industry and moved to the United States to work for Coherent in 1984. In 1985 Willie Firth was attracted from Heriot-Watt University and built a very successful theory group including the later appointments of Gian-Luca Oppo and Steve Barnett.

In the early 1980s the senior management of the University of Strathclyde decided that laser science and engineering had a long-term place in the university portfolio and took the then unprecedented step of creating an established Chair of Photonics. This is thought to be the first chair of its type created by any university. The Chair of Photonics was initially filled by Brian Henderson who moved from Trinity College, Dublin in 1982. Brian brought with him expertise in the optical properties of solids. He created a research activity in semiconductor and crystalline solids including the establishment of a large laser crystal growth facility.

It was against this background that Allister Ferguson moved from Southampton and was appointed to the Chair of Photonics in 1989 (Henderson having been translated to the Chair of Natural Philosophy established in 1796). Allister’s arrival brought an interest in the emerging area of diode laser pumped solid state lasers, non-linear optics and high-resolution laser spectroscopy. The Photonics Group was created with Erling Riis who moved from Steve Chu’s group in Stanford and Nigel Langford who had been a student of Wilson Sibbett at St Andrews.

Allister Ferguson was charged with not only setting up a research group but also with building closer links to industry. The first step on this journey was the creation of Microlase Optical Systems Ltd. Microlase was created with Graeme Malcolm (one of Allister Ferguson’s first Strathclyde research students) and Gareth Maker (one of his last research students at Southampton). The company was based on single frequency Ti:sapphire lasers, diode-pumped solid-state lasers (DPSSLs) and non-linear optical devices. It grew rapidly through the 1990s, was sold to Coherent in 1999 and became Coherent Scotland Ltd. It was initially run by Graeme Malcolm and Gareth Maker until they left to form M-Squared Lasers Ltd. Coherent Scotland and M-Squared employ more than 250 people in Glasgow.

Encouraged by senior management at Strathclyde, Allister Ferguson created a new vehicle for engagement with industry in lasers by establishing the institute of Photonics in 1995. The institute was initially supported by Scottish Enterprise and Thales. The aim of the institute of Photonics was, and continues to be, to bridge the gap between academia and industry. Applied research at the institute has centred on advanced laser engineering and photonic materials and devices. More recently it has moved into Neurophotonics under the leadership of Keith Mathieson. The Institute was run as a self-funded unit with a Chief Executive (Karen Ness, ex Imperial College, followed by Tim Holt, ex Ferranti and Rofin).

One of the first employees at the Institute of Photonics was Martin Dawson (ex Sibbett group at Imperial). Dawson together with Holt and Ferguson developed the notion of setting up an intermediary organization to work between academia and industry. Holt’s experience of the German system led to discussions with Fraunhofer Gesellschaft culminating in the establishment of Fraunhofer Research UK Ltd and its subsidiary Fraunhofer Centre for Applied Photonics (FCAP) in 2012. FCAP is led by Martin Dawson who is a joint appointee between Strathclyde and Fraunhofer. Laser engineering at FCAP builds on the laser research at the Institute of Photonics. FCAP has the skills and capacity to build prototypes closer to the final form needed by industry.

Close working with industry has been at the heart of the Strathclyde laser research and the university has worked hard to help create a photonic cluster. The emergence of a cluster of new companies alongside the established laser companies led to the creation of the Scottish Optoelectronics Association (SOA) in 1994 with the mission of promoting the industry in Scotland. As part of the celebration of the 50th anniversary of the invention of the laser, known as Laserfest (see Figure 19), the SOA produced a report showing that in 2009 the laser industry contributed £660 million to the Scottish economy^[149]. The University of Strathclyde celebrated Laserfest by awarding 11 laser-related Nobel laureates honorary degrees.

Figure 19

Allister Ferguson at the Laserfest event at the Glasgow Science Centre where ‘50 Years of the Laser in Scotland’ was launched. Speakers at the event included Nobel laureates Steve Chu, Roy Glauber and Eric Cornell. Local speakers included Dave Hanna, Ed Hinds and Steve Barnett.

A report by Photonics Scotland (formerly known as SOA) in 2020 indicated that the photonics sector in Scotland produced £1.2 billion in revenue from 60 companies employing more than 5700 people^[149].

As the laser research at Strathclyde has migrated from the Photonics Group in the Department of Physics to the Institute of Photonics and to FCAP, photonics research at Strathclyde has moved toward opportunities associated with quantum technology. The foundation of this work comes from the appointment of Erling Riis establishing one of the first UK efforts in laser cooling and trapping of atoms in the early 1990s. Strathclyde research is a key part of the UK national strategy in quantum technology. Strathclyde is well set to make its contribution to this emerging and transformational technology as it has done and continues to do with laser technology.

Laser–plasma research

Laser–plasma research at the University of Strathclyde started in 1998 when Dino Jaroszynski won a national competition to acquire an 800 nm, 1 kHz, femtosecond Ti:sapphire laser system from the then British Nuclear Fuels Ltd (BNFL). His vision, at the time, was to instigate a completely new direction in plasma research at Strathclyde, and importantly, exploring applications of novel laser–plasma technology for the benefit of society, while simultaneously supporting creative intellectual endeavour. What was set in motion in 1998 was not just a new UK laser–plasma research activity, to which Strathclyde contributed, but something quite different. Dino’s previous research experience on free-electron lasers (FELs), starting at Heriot-Watt University on the UK-FEL^[Reference Pidgeon, Jaroszynski, Tratt, Smith, Firth, Kimmitt, Cheng, Poole, Saxon, Walker, Mackay, Reid, Kelliher, Laing, Land and Gillespie^150] in 1982, provided the insight of combining laser–plasma research for developing radiation sources with basic science research; the unique radiation sources would be used by a diverse community^[Reference Jaroszynski and Vieux^151, Reference Jaroszynski, Bingham, Brunetti, Ersfeld, Gallacher, van der Geer, Issac, Jamison, Jones, de Loos, Lyachev, Pavlov, Reitsma, Saveliev, Vieux and Wiggins^152]. Figure 20 shows several of the UK-FEL team members and Figure 21 the undulator at Kelvin Laboratory in East Kilbride, circa 1983.

Figure 20

Several of the UK-FEL team members (from left to right) Dino Jaroszynski, Maurice Kelliher, Maurice Kimmitt, and person unknown.

Figure 21

The UK-FEL undulator at Kelvin Laboratory, East Kilbride circa 1983.

The experience Dino gained in contributing to setting up two FEL facilities, FELIX^[Reference Jaroszynski, Bakker, Vandermeer, Oepts and Vanamersfoort^153–Reference Jaroszynski, Chaix, Piovella, Oepts, Knippels, vanderMeer and Weits^155] in the Netherlands (which incorporated the old UK-FEL undulators) and CLIO^[Reference Jaroszynski, Prazeres, Glotin and Ortega^156, Reference Jaroszynski, Prazeres, Glotin, Ortega, Oepts, van der Meer, Knippels and van Amersfoor^157] in France, laid the groundwork for the nascent programme at Strathclyde; by combining two previously unconnected areas of research, a very novel research area would be established. Motivated by this vision of a paradigm shifting technology, a new research area was established at the university of Strathclyde. The journey to realize it began with securing support from the university and winning several large grants from the UK Research Councils, the Scottish Universities Physics Alliance (SUPA) and the Scottish Funding Council (SFC).

In 2000, Dino’s team was the first in the world to suggest using a laser–plasma accelerator to drive an FEL^[Reference Jaroszynski and Vieux^151, Reference Jaroszynski, Bingham, Brunetti, Ersfeld, Gallacher, van der Geer, Issac, Jamison, Jones, de Loos, Lyachev, Pavlov, Reitsma, Saveliev, Vieux and Wiggins^152, Reference Jaroszynski, Ersfeld, Giraud, Jamison, Jones, Issac, McNeil, Phelps, Robb, Sandison, Vieux, Wiggins and Wynne^158], which has stimulated major initiatives across the globe (e.g., EuPRAXIA^[Reference Weikum, Akhter, Alesini, Alexandrova, Anania, Andreev, Andriyash, Aschikhin, Assmann, Audet, Bacci, Barna, Beaton, Beck, Beluze, Bernhard, Bielawski, Bisesto, Brandi, Brinkmann, Bruendermann, Büscher, Bussmann, Bussolino, Chance, Chen, Chiadroni, Cianchi, Clarke, Cole, Couprie, Croia, Cros, Crump, Dattoli, Del Dotto, Delerue, De Nicola, Dias, Dorda, Fedele, Pousa, Ferrario, Filippi, Fiore, Fonseca, Galimberti, Gallo, Ghaith, Giove, Giribono, Gizzi, Grüner, Habib, Haefner, Heinemann, Hidding, Holzer, Hooker, Hosokai, Huebner, Irman, Jafarinia, Jaroszynski, Joshi, Kaluza, Kando, Karger, Karsch, Khazanov, Khikhlukha, Knetsch, Kocon, Koester, Kononenko, Korn, Kostyukov, Kruchinin, Labate, Blanc, Lechner, Leemans, Lehrach, Li, Libov, Lifschitz, Litvinenko, Lu, Lundh, Maier, Malka, Manahan, Mangles, Marchetti, de la Ossa, Martins, Mason, Massimo, Mathieu, Maynard, Mazzotta, Molodozhentsev, Mostacci, Mueller, Murphy, Najmudin, Nghiem, Nguyen, Niknejadi, Osterhoff, Espinos, Papadopoulos, Patrizi, Petrillo, Pocsai, Poder, Pompili, Pribyl, Pugacheva, Rajeev, Romeo, Conti, Rossi, Rossmanith, Roussel, Sahai, Sarri, Schaper, Scherkl, Schramm, Schroeder, Scifo, Serafini, Sheng, Siders, Silva, Silva, Simon, Sinha, Specka, Streeter, Svystun, Symes, Szwaj, Tauscher, Terzani, Thompson, Toci, Tomassini, Torres, Ullmann, Vaccarezza, Vannini, Vieira, Villa, Wahlstrom, Walczak, Walker, Wang, Welsch, Wiggins, Wolfenden, Xia, Yabashi, Zhu and Zigler^159]). Research in laser–plasma accelerators took off at Strathclyde in 2002 with the award of a UK Research Council Basic Technology Project, which funded the ALPHA-X^[Reference Jaroszynski and Vieux^151, Reference Jaroszynski, Bingham, Brunetti, Ersfeld, Gallacher, van der Geer, Issac, Jamison, Jones, de Loos, Lyachev, Pavlov, Reitsma, Saveliev, Vieux and Wiggins^152] (Advanced Laser-Plasma High-energy Accelerators towards X-rays) project (Figure 22). The project, led by Strathclyde, involved Imperial College London, University of Oxford, CLF, University of St Andrews and the University of Abertay Dundee, made several world-leading breakthroughs in laser–plasma wakefield accelerators (LWFAs) and radiation sources, including the first experimental demonstration of the laser–plasma electron accelerator (CLF experiments led by the Imperial College team), published in Nature as one of the ‘Dream Beam’ papers^[Reference Mangles, Murphy, Najmudin, Thomas, Collier, Dangor, Divall, Foster, Gallacher, Hooker, Jaroszynski, Langley, Mori, Norreys, Tsung, Viskup, Walton and Krushelnick^82], its use as a source of synchrotron radiation^[Reference Schlenvoigt, Haupt, Debus, Budde, Jäckel, Pfotenhauer, Schwoerer, Rohwer, Gallacher, Brunetti, Shanks, Wiggins and Jaroszynski^160], gamma rays^[Reference Cipiccia, Islam, Ersfeld, Shanks, Brunetti, Vieux, Yang, Issac, Wiggins, Welsh, Anania, Maneuski, Montgomery, Smith, Hoek, Hamilton, Lemos, Symes, Rajeev, Shea, Dias and Jaroszynski^161] and femtosecond to attosecond electron bunches^[Reference Tooley, Ersfeld, Yoffe, Noble, Brunetti, Sheng, Islam and Jaroszynski^162, Reference Islam, Brunetti, Shanks, Ersfeld, Issac, Cipiccia, Anania, Welsh, Wiggins, Noble, Cairns, Raj and Jaroszynski^163]. It also stimulated laser–plasma research at the Cockcroft Institute in 2008, through an agreement made with its then Director, Swapan Chattopadhyay, who invited Strathclyde to join the Cockcroft Institute as an Associate Member, with Strathclyde later joining as a full member.

Figure 22

Left: ALPHA-X team members in the control area of the TOPS laboratory on the first electron beam in March 2007, (left to right) Riju Issac, Gregory Vieux, Richard Shanks and Enrico Brunetti. Right: First electrons on the SCAPA ALPHA-X beamline in Bunker C in 2017, 10 years later, (left to right) Mohammed Shahzad, Gregory Welsh, Enrico Brunetti and Giorgio Battaglia.

These growing research endeavours attracted several leading scientists to Strathclyde, including Ken Ledingham, Paul McKenna, Zheng-Ming Sheng and Bernhard Hidding, who created the germ of a new research activity that grew into four thriving teams that now include more than 50 people from across the university, which has put Strathclyde firmly on the map in the field. The teams now constitute the Strathclyde Intense Laser Interaction Studies (SILIS) group.

Establishing new facilities, including SCAPA

The initial activity, starting with the BNFL laser, resulted in the TOPS (Terahertz to Optical Pulse Source) facility^[Reference Jaroszynski, Ersfeld, Giraud, Jamison, Jones, Issac, McNeil, Phelps, Robb, Sandison, Vieux, Wiggins and Wynne^158], which transformed into the ALPHA-X project, and finally into SCAPA^[Reference Wiggins, Boyd, Brunetti, Butler, Feehan, Gray, Hidding, Ireland, Li, Maitrallain, Manahan, McKenna, O’Donnell, Scheck, Shahzad, Sheng, Spesyvtsev, Vieux, Watts, Welsh, Wilson, Zachariou and Jaroszynski^164]. The ALPHA-X project was developed around a 4 TW, Ti:sapphire laser (Figure 23), which was progressively upgraded to 40 TW. SCAPA, a brand-new university-based laser facility, was conceived in 2007 as a user facility based on the beamline concept. However, it was not until 2010 that plans for building the 1200 m² SCAPA infrastructure were drawn up as part of the University Estates Development Framework (EDF) and progress was made towards establishing the facility. Plans for the SCAPA infrastructure to be situated in the John Anderson Building at Strathclyde were completed by 2014 (under the technical management of Mark Wiggins) and building started in earnest to create three vibrationally isolated ‘bunkers’ (radiation shields), laser cleanrooms and ancillary rooms.

Figure 23

Left: The 4 TW TOPS facility in 2002. Right: Dr. Riju Issac who developed laser–cluster interaction-based X-ray sources.

In 2016, when access was gained to the building, work started on installing the old 40 TW laser and beamlines, initially the ALPHA-X beamline and then three other beamlines, including a laser wakefield (Bunker A), laser–solid (Bunker B) and a medical beamline (Bunker C) shown in Figure 24. ‘Snagging’ continued until 2018, which severely hampered progress.

Figure 24

The SCAPA laser facility interaction areas: (a) Beamline A2 in Bunker A; (b) Beamline B2 in Bunker B; and (c) work in progress on the ALPHA-X/medical beamline in Bunker C.

The university invested in a world-leading commercial 350 TW laser from Thales (Figure 25), which was delivered in 2016 and commissioned in January 2017 to form the unique facility, which now includes three vibrationally isolated bunkers with large rapid-close concrete doors and seven beamlines. Funds were obtained in 2017 to create several beamlines, and in 2020 work started on developing a 0.6 TW, kilohertz laser laboratory at SCAPA. In 2019 funding was obtained to build a novel beamline, Plasma Accelerators for Nuclear Applications and Materials Analysis (PANAMA).

Figure 25

The SCAPA Thales 5 Hz, 350 TW laser.

Research activities of the SILIS group

In parallel to the SCAPA building programme, the group at Strathclyde grew rapidly.

Dino Jaroszynski’s group currently undertakes research using lasers on laser-driven accelerators and radiation sources, including an LWFA-driven FEL^[Reference Jaroszynski and Vieux^151, Reference Jaroszynski, Bingham, Brunetti, Ersfeld, Gallacher, van der Geer, Issac, Jamison, Jones, de Loos, Lyachev, Pavlov, Reitsma, Saveliev, Vieux and Wiggins^152, Reference Jaroszynski, Bingham, Brunetti, Ersfeld, Gallacher, van der Geer, Issac, Jamison, Jones, de Loos, Lyachev, Pavlov, Reitsma, Saveliev, Vieux and Wiggins^152, Reference Jaroszynski, Ersfeld, Islam, Brunetti, Shanks, Grant, Tooley, Grant, Gil, Lepipas, McKendrick, Cipiccia, Wiggins, Welsh, Vieux, Chen, Aniculaesei, Manahan, Anania, Noble, Yoffe, Raj, Subiel, Yang, Sheng, Hidding, Issac, Cho and Hur^165], and the ion channel laser (ICL)^[Reference Ersfeld, Bonifacio, Chen, Islam, Smorenburg and Jaroszynski^166]. They have constructed a state of the art S-band 2.5 cell photo-injector^[Reference de Loos, van der Geer, Saveliev, Pavlov, Reitsma, Wiggins, Rodier, Garvey and Jaroszynski^167], which is on loan to Daresbury Laboratories and now forms part of the VELA/CLARA accelerator. His group undertook a series of unique experiments to demonstrate production of visible radiation and 20 fs pulses of 60–120 nm VUV radiation from an LWFA-driven undulator^[Reference Anania, Brunetti, Wiggins, Grant, Welsh, Issac, Cipiccia, Shanks, Manahan, Aniculaesei, van der Geer, de Loos, Poole, Shepherd, Clarke, Gillespie, MacLeod and Jaroszynski^168, Reference Jaroszynski, Anania, Aniculaesei, Battaglia, Brunetti, Chen, Cipiccia, Ersfeld, Gil, Grant, Grant, Hur, Gamiz, Kang, Kokurewicz, Kornaszewski, Li, Maitrallain, Manahan, Noble, Reid, Shahzad, Spesyvtsev, Subiel, Tooley, Vieux, Wiggins, Welsh, Yoffe and Yang^169]. They also investigated diverse subjects such as working towards constructing an LWFA-driven FEL, investigating Raman amplification^[Reference Ersfeld and Jaroszynski^170–Reference Yang, Vieux, Brunetti, Ersfeld, Farmer, Hur, Issac, Raj, Wiggins, Welsh, Yoffe and Jaroszynski^174], terahertz sources^[Reference Jamison, Shen, Jones, Issac, Ersfeld, Clark and Jaroszynski^175–Reference Jamison, Shen, MacLeod, Gillespie and Jaroszynski^177], laser–cluster interactions^[Reference Issac, Vieux, Ersfeld, Brunetti, Jamison, Gallacher, Clark and Jaroszynski^178], ultra-high charge beams^[Reference Yang, Brunetti, Gil, Welsh, Li, Cipiccia, Ersfeld, Grant, Grant, Islam, Tooley, Vieux, Wiggins, Sheng and Jaroszynski^179, Reference Brunetti, Yang and Jaroszynski^180], electromagnetically induced transparency^[Reference Ersfeld and Jaroszynski^181], gamma ray sources^[Reference Cipiccia, Islam, Ersfeld, Shanks, Brunetti, Vieux, Yang, Issac, Wiggins, Welsh, Anania, Maneuski, Montgomery, Smith, Hoek, Hamilton, Lemos, Symes, Rajeev, Shea, Dias and Jaroszynski^161, Reference Cipiccia, Vittoria, Weikum, Olivo and Jaroszynski^182], high-field physics^[Reference Kravets, Noble and Jaroszynski^183, Reference Macleod, Noble and Jaroszynski^184] and very-high-energy electron (VHEE) radiotherapy^[Reference Subiel, Moskvin, Welsh, Cipiccia, Gil, Evans, Partridge, Desrosiers, Anania, Cianchi, Mostacci, Chiadroni, Giovenale, Villa, Pompili, Ferrario, Bellaveglia, Di Pirro, Gatti, Vaccarezza, Seitz, Issac, Brunetti, Wiggins, Ersfeld, Islam, Mendonca, Sorensen, Boyd and Jaroszynski^185–Reference Kokurewicz, Brunetti, Welsh, Wiggins, Boyd, Sorensen, Chalmers, Schettino, Subiel, DesRosiers and Jaroszynski^187].

Paul McKenna’s group focuses on the physics of high-power laser–matter interactions. The group has made important contributions to laser-driven ion acceleration and applications, including investigation of the scaling of ion beam properties at petawatt powers^[Reference Robson, Simpson, Clarke, Ledingham, Lindau, Lundh, McCanny, Mora, Neely, Wahlström, Zepf and McKenna^188], the use of multiple drive laser pulses, the first use of tens-of-nanometres-thick targets to enhance ion acceleration^[Reference Neely, Foster, Robinson, Lindau, Lundh, Persson, Wahlstrom and McKenna^189, Reference Gonzalez-Izquierdo, King, Gray, Wilson, Dance, Powell, MacLellan, McCreadie, Butler, Hawkes, Green, Murphy, Stockhausen, Carroll, Booth, Scott, Borghesi, Neely and McKenna^190], and the production of near-100 MeV protons in targets undergoing relativistic self-induced transparency^[Reference Higginson, Gray, King, Dance, Williamson, Butler, Wilson, Capdessus, Armstrong, Green, Hawkes, Martin, Wei, Mirfayzi, Yuan, Kar, Borghesi, Clarke, Neely and McKenna^191]. The group has investigated the fundamental physics of fast electron transport in solids, including studies correlating the degree of ordering of the lattice structure of a material to its electrical resistivity in the transient warm dense matter state^[Reference McKenna, Carroll, Clarke, Evans, Ledingham, Lindau, Lundh, McCanny, Neely, Robinson, Robson, Simpson, Wahlstrom and Zepf^192–Reference MacLellan, Carroll, Gray, Booth, Burza, Desjarlais, Du, Neely, Powell, Robinson, Scott, Yuan, Wahlström and McKenna^195] (relevant to the development of advanced ignition schemes for inertial fusion). They are exploring the physics of high-field phenomena such as radiation reaction and radiation generation in dense plasma in preparation for experiments at ultra-high intensities using multi-petawatt lasers^[Reference Capdessus and McKenna^196, Reference Capdessus, King, Del Sorbo, Duff, Ridgers and McKenna^197]. In collaboration with the CLF, they have optimized the performance of plasma mirrors including focusing geometries to increase laser intensities by up to an order of magnitude and have performed pioneering studies of relativistic plasma optics and photonics phenomena^[Reference Gonzalez-Izquierdo, Gray, King, Dance, Wilson, McCreadie, Butler, Capdessus, Hawkes, Green, Borghesi, Neely and McKenna^198, Reference Duff, Wilson, King, Gonzalez-Izquierdo, Higginson, Williamson, Davidson, Capdessus, Booth, Hawkes, Neely, Gray and McKenna^199]. Most of this research has been performed using high-power lasers at the CLF, Laserlab-Europe facilities, and a number of other international laser laboratories, in collaboration with national and international researchers.

Zheng-Ming Sheng’s research focuses on the theory and simulation of relativistic laser–plasma interactions, plasma-based particle accelerators and radiation sources relevant to the SCAPA experimental programmes and high-field studies for the next-generation lasers such as at the Extreme Light Infrastructure (ELI) and EPAC at the CLF. He and his co-workers have proposed several new injection schemes to control the beam quality in the LWFA, including ionization-controlled injection using two-colour lasers, density gradient controlled injection and magnetic field-controlled injection^[Reference Zeng, Chen, Yu, Mori, Sheng, Hidding, Jaroszynski and Zhang^200–Reference Zhao, Weng, Sheng, Chen, Zhang, Mori, Hidding, Jaroszynski and Zhang^202]. To reach teraelectronvolt energy levels of LWFA they developed a theory for coupling multiple-stage accelerators^[Reference Luo, Chen, Wu, Weng, Sheng, Schroeder, Jaroszynski, Esarey, Leemans, Mori and Zhang^203]. They investigated novel plasma-based X-ray sources that are both brilliant and have ultra-short duration, with photon energies extending to gamma-rays through betatron radiation via plasma channels, two stage LWFA acceleration and laser–wire acceleration, etc.^[Reference Chen, Luo, Li, Liu, Sheng and Zhang^204–Reference Wang, Sheng, Gibbon, Chen, Li and Zhang^206]. His studies of the generation of broadband terahertz and few-cycle mid-IR have many applications in probing materials^[Reference Yu, Zhao, Qian, Chen, Weng, Sheng, Jaroszynski, Mori and Zhang^207–Reference Zhang, Chen, Cui, He, Chen, Zhang, Yu, Chen, Sheng and Zhang^209]. With further development of laser technology, multi-petawatt laser systems such as the ELI facilities in Europe, QED plasma can be produced, and extreme states of matter explored, including electron-positron pair production and brilliant gamma-ray sources, could be tested experimentally in the near future^[Reference Zhu, Yu, Sheng, Yin, Turcu and Pukhov^210, Reference Wang, Sheng, Wilson, Li and Zhang^211]. These are not only interesting and relevant to plasma-based electron accelerators but are also relevant to astrophysical phenomena.

Bernhard Hidding’s research focuses mainly on beam-driven plasma wakefield accelerators^[Reference Deng, Karger, Heinemann, Knetsch, Scherkl, Manahan, Beaton, Ullmann, Wittig, Habib, Xi, Litos, O’Shea, Gessner, Clarke, Green, Lindstrøm, Adli, Zgadzaj, Downer, Andonian, Murokh, Bruhwiler, Cary, Hogan, Yakimenko, Rosenzweig and Hidding^212, Reference Manahan, Habib, Scherkl, Delinikolas, Beaton, Knetsch, Karger, Wittig, Heinemann, Sheng, Cary, Bruhwiler, Rosenzweig and Hidding^213] that hope to produce ultra-high brightness beams for various applications^[Reference Hidding, Karger, Königstein, Pretzler, Manahan, McKenna, Gray, Wilson, Wiggins, Welsh, Beaton, Delinikolas, Jaroszynski, Rosenzweig, Karmakar, Ferlet-Cavrois, Constantino, Muschitiello and Daly^214].

3.2.1 Early years: the setting up of the CLF

There was strong research activity within the UK academic community in the area of laser–plasma interactions with lasers at the University of Hull and QUB, and strong research interests at Imperial College London, University of Essex and Swansea University. It was difficult, though, to compete with work carried out at national laboratories worldwide. A committee of senior UK academics chaired by Professor Dan Bradley (QUB and Imperial College London), Dr. Dave Burgess (Imperial College London), Dr. John Colles (Heriot-Watt University), Professor Colyn Grey Morgan (University College Swansea), Dr. Malcolm Haines (Imperial College London), Mr. Tom Hughes (University of Essex), Dr. Mike Key (QUB), Dr. Geoff Pert (University of Hull), Professor Stuart Ramsden (University of Hull) and Dr. Eric Wooding (Royal Holloway College) was formed circa 1973 to discuss setting up a national high-power laser facility. There was discussion about hosting this facility within a university, either QUB or Hull. The increasing issues with the political conflict in Northern Ireland ruled out Belfast as a viable option. A laser facility already existed at AWRE and the option was proposed that academics could also access that facility; it was thought by some that two separate facilities serving the defence and academic communities could lead to funding issues. It was eventually decided that a large central laser facility would be the best option to put the country in a competitive world position.

In July 1974, the Chairman of the SRC, Sir Sam Edwards, called a meeting to discuss the proposal to build a large laser facility at the Rutherford Laboratory, tabled by Godfrey Stafford, Director of Rutherford Laboratory. At the time Rutherford was predominately a laboratory for the study of high-energy nuclear physics based around the Nimrod proton accelerator. However, the superior engineering capabilities within a large national laboratory were widely recognized as a key advantage and eventually it was agreed to build a facility at the Rutherford Laboratory dedicated to the needs of the academic community.

The CLF was intended from the start to provide laser facilities for use by university and polytechnic research groups^[265]. The CLF received UK governmental approval in October 1975 under its first Director Alan Gibson (formerly founding Head of Physics Department, University of Essex). Space was made available at the Rutherford Laboratory in Oxfordshire (eventually to be RAL) in April 1976.

The CLF was soon up and running with the installation of a Nd:glass laser (later to be called VULCAN). Paul Williams led the laser facility development. Operations began with a single beam delivering 100 ps pulses at a power of 100 GW, in December 1976, using technology supplied by JK Lasers Ltd, Rugby and Quantel, France. April 1977 saw the completion of the commissioning of the disc amplifiers, supplied by ILC (International Lamp Corporation) to LLNL, USA design.

The Laser Facility was formally inaugurated by Sir Sam Edwards, Chairman of the SRC, on Monday 20 June 1977, shown in Figure 29, hosted by Professor Alan Gibson, Director of the CLF, and Dr. Paul Williams, Deputy Director and later Director of RAL. The inauguration included the successful firing of a Nd:glass laser facility shot.

Figure 29

The inauguration of the CLF with, from left to right, Professor Alan Gibson, Professor Dan Bradley, Sir Sam Edwards and Godfrey Stafford, RAL Director. (Picture courtesy of STFC.)

High-power plasma experiments started immediately, initially in to one target area, but within a year a second target area (TA2) was brought on-line. Experimental programmes were coordinated by Tom Hughes (University of Essex) and Dr. Mike Key (QUB). Detailed proposals originated primarily from groups which were convened by:

• • Dr. Joe Kilkenny, Imperial College London, optical and magnetic measurements;

• • Dr. Brian Fawcett, Appleton Laboratory, X-ray and XUV spectroscopy;

• • Dr. Tom Hall, University of Essex, optical spectroscopy;

• • Dr. Howard Miles, Swansea University, particle emission studies;

• • Dr. Richard Dewhurst, University of Hull, gas breakdown;

• • Dr. Nick Peacock, Culham Laboratory, X-ray lasers and harmonic generation;

• • Professor Malcolm Haines, Imperial College London, theoretical and computational support.

The group structure evolved rapidly to target scientific objectives, together with committees to advise on the scientific programme, and on the scheduling of proposals. The programme was overseen by the Laser Facility Committee (LFC) whose membership was made up of the university users.

In 1980, Alan Gibson decided that the Nd:glass laser should be renamed something more media-friendly. Various suggestions were made including ‘British Universities’ Neodymium Glass Laser Equipment’ (BUNGLE), but the eventual choice was a name derived from Latin proposed by Roger Evans: VULCAN (Versicolor Ultima Lux Coherens pro Academica Nostra) or ‘The latest multi-coloured coherent light for our academics’^[Reference Key^35].

3.2.2 The laser programmes

Gas/excimer laser programme. Following the setting up of the CLF there was some initial CO₂ laser development, with Alan Gibson at the helm, but this was quickly phased out.

In the late 1970s there was a strong interest in inertial-fusion applications, and the development of high-power lasers, which would directly produce light at the necessary UV wavelengths. Excimer gas lasers using KrF or ArF, pumped by Marx generators, were a leading candidate to meet this criterion. The CLF embarked on a programme of laser development of these systems.

The construction of an Electron-beam excited Laser Facility (ELF) started in 1978 to a general design supplied by AWRE with commissioning being completed in March 1979. ELF was the first pulsed excimer laser in the world using ArF operating at UV wavelengths (193 nm). It was initially intended to act as a pump to investigate the selenium laser operating at 488 nm. The laser produced 3 kJ of energy in a 50 ns pulse. The electron beam itself was 5 × 50 cm² and could operate up to 1.5 MeV.

Work on a new e-beam pumped KrF laser operating at 249 nm started in 1981 to provide increased capability. The laser known as Sprite^[Reference Lister, Divall, Downes, Edwards, Hirst, Hooker, Key, Ross, Shaw and Toner^266] was used to develop the next generation of high-power gas lasers and study bright X-ray sources. It had a 27 cm aperture e-beam pumped gas cell, shown in Figure 30. Sprite had an e-beam pumped KrF pre-amplifier laser system named Goblin, which used repurposed ELF hardware.

Figure 30

Dave Wood shown with the Sprite e-beam pumped amplifier cell in 1982. (Picture courtesy of STFC.)

Sprite was initially used in a seeded unstable-resonator configuration to generate long, ~60 ns, pulses for irradiation experiments. With increasing interest in shorter pulses, for which Sprite would be used as an amplifier, it was obvious that the long duration of the electron beam combined with the short optical path through the gain medium would lead to very inefficient energy extraction, because KrF is not an energy-storage medium. A time-multiplexed arrangement, in which nanosecond duration pulses were sent through the amplifier at regular intervals on angularly separated beam paths, allowed the majority of the electron-beam energy to be extracted from the gain medium.

To make efficient use of the energy extracted with multiple KrF beams, a scheme of Raman beam combination was developed^[Reference Ross, Shaw, Hooker, Key, Harvey, Lister, Andrew, Hirst and Rodgers^267]. This used stimulated Raman scattering in methane gas to transfer the energy of a number of 249 nm KrF laser beams into a single beam at a wavelength of 268 nm. Of the eight multiplexed KrF beams, one was used to pump a Raman preamplifier, and the remaining seven pumped a second power amplifier whose single output combined 70%–80% of the total pump energy. Seed pulses for both the KrF and Raman amplifiers were generated in a front-end, which over the years developed through various technologies from discharge-pumped excimer lasers, to dye lasers and then titanium-doped sapphire. A fraction of the initial KrF pulse was focused into a methane gas cell, and the first Stokes beam was selected from the spectrum of pulses emerging from the cell to form the seed for the Raman amplifiers. The multiplexing technique was initially used with nanosecond-duration pulses, delivering up to 100 J of energy, and was later also applied to pulses of 12 ps duration once a short-pulse dye laser was introduced in the front-end. The advantage of the Raman combining scheme is that it generates near-diffraction-limited pulses in a high-contrast beam; ideal for clean high-intensity operation.

By 1983, Sprite was the most powerful operational KrF laser in the world, and in 1984 it became the world’s first high-power KrF laser to be used for the irradiation of targets, supporting a full scheduled user interaction programme. At pulse lengths of 3.5 ps it demonstrated energies of 2.5 J giving a peak power of 0.7 TW^[Reference Barr, Everall, Hooker, Ross, Shaw and Toner^268]. One of its main advantages for an ultra-high-intensity laser was that it had a relatively high shot rate, being able to fire 12 shots per hour. Experiments for the academic community covered a broad range of studies from laser/plasma interaction studies, X-ray laser investigations and work on multi-phonon ionization in gases. In an unusual experiment Sprite was used to calibrate the dust sensor for the Giotto space probe mission to Halley’s comet by firing laser pulses at the dust shields of the satellite, taking advantage of the cross-disciplinary nature of RAL. The energy and duration of a laser shot were similar to those of a small dust particle impacting the shield.

The technique of CPA^[Reference Strickland and Mourou^50] was also implemented on Sprite in 1992–1993. The gain bandwidth in KrF is broad enough to support pulse amplification at pulse durations of <100 fs. The configuration used on Sprite generated the ultra-short pulses in Ti:sapphire at 746 nm, frequency tripled the output to produce pulse of 249 nm, and then stretched the pulse to ~12 ps prior to amplification. Amplification took place in three stages: a pre-amplifier, Goblin and then the main Sprite output amplifier. Asymmetric gain narrowing in the three amplifier stages limited the compressed pulse duration to 300 fs with 300 mJ on target, delivering 1 TW, with focused intensities >10¹⁹ W·cm^–2.

Sprite’s last shot was fired by Paul Williams in a small ceremony on 31 March 1995; it was then repurposed as the pre-amplifier for a new laser called Titania. Titania^[Reference Divall, Edwards, Hirst, Hooker, Kidd, Lister, Mathumo, Ross, Shaw, Toner, Visser and Wyborn^269, Reference Hirst, Divall, Edwards, Hooker, Key, Kidd, Knott, Lister, Neely, Norreys, Ross, Shaw and Wyborn^270] was designed to have 10 times the energy of Sprite to produce higher brightness than any other laser in the UV range. The inauguration of the facility took place on 2 April 1996 by Mike Key (CLF Director) and Paul Williams (CEO of CCLRC) successfully firing a test shot.

Titania, like Sprite, could be operated in two alternative modes, CPA (249 nm) and Raman (268 nm), which could deliver peak intensities to target of 10¹⁹ W·cm^–2 with f/3 focusing optics. The first mode, which became operational in 1996, used CPA to produce pulses of 300 fs with a pulse energy of 6–8 J from the 42 cm aperture final e-beam pumped amplifier. Smaller aperture compression gratings used to recompress the pulse limited the energy on target to <10% of this.

The energy limitations of the CPA scheme were removed in an alternative architecture that was based on Raman beam combination. Here the KrF amplifier’s energy was extracted by a train of 24 short pulses, each of which can have an energy of up to 8 J. These pulses were then resynchronized and used to pump a chain of methane-filled Raman amplifiers which combined into one pulse with an efficiency of up to 70%, delivering pulses of 30–500 ps duration. As well as the increased energy, other benefits included higher beam quality and ultra-high contrast pulses.

The VULCAN laser facility. In 1980 the CLF’s Nd:glass laser, now called VULCAN, was upgraded to deliver six 1053 nm, 108 mm diameter beams to target, 300 J per beam at 1 ns, with an additional full aperture beam used largely for X-ray backlighting^[Reference Ross, White, Boon, Craddock, Damerell, Day, Gibson, Gottfeldt, Nicholas and Reason^271], and the output disc amplifier array is shown in Figure 31. At the same time, synchronized long- and short-pulse oscillators^[Reference White, Damerell, Hodgson, Ross, Wyatt and Ireland^272] were installed in a system designed by Malcolm White. It was a world’s first, allowing the synchronization of a laser-driven implosion pulse with an X-ray diagnostic backlighting pulse. This system used an actively mode-locked and Q-switched 70 ps Nd:YLF oscillator, developed by JK Lasers, and a Q-switched Nd:YLF multi-nanosecond pulse oscillator from which a synchronized nanosecond slice could be delivered using an Austin switch (laser-driven high-voltage switch) driven Pockels cells, giving ultra-low temporal jitter (≲5 ps).

Figure 31

The VULCAN laser hall showing the output disc amplifiers with Colin Danson, foreground, and Bob Bann carrying out final system alignment circa 1986. (Picture courtesy of STFC.)

This established the facility as world class, with researchers collaborating with the UK leads from around the world. The upgrade also saw the first of a number of building additions with two new target areas TAE (Target Area East) and TAW (Target Area West) coming on-line to exploit the increased capability. The six beams were also converted to green to reduce the fast-electron heating and improve the implosion performance of microspheres.

The laser system was completely rebuilt in 1988–1989 with in-house designed rod and disc amplifiers. The disc amplifiers had an improved box design, giving good beam quality whilst being able to fire every 20 minutes. The auxiliary backlighter beam was upgraded by being split into two parallel arms that boosted the total energy to 1 kJ, using two 15 cm aperture disc amplifiers of CLF box design.

The main research programmes on VULCAN at this time included: XUV and X-ray lasers; applications of laser-produced plasma sources; laser–plasma interactions and energy transport; laser compression and dense plasmas; and later ultra-high-power laser–plasma interactions.

The development of all the lasers within the CLF has largely been driven by the requirements of the user community. This is exemplified by the development of ultra-short pulse lasers, and in particular CPA on VULCAN. The initial driver for this development was for electron acceleration studies. VULCAN had been adapted to study the beat-wave electron acceleration technique through the mid-1980s^[Reference Dangor, Afshar-Rad, Cole, Danson, Dymoke-Bradshaw, Dyson, Edwards, Evans, Garvey and Mitchell^49], where two wavelengths were generated and amplified to interact in a pre-formed plasma. Alternative acceleration schemes started focussing on ultra-short pulse interactions following the concept of the laser wakefield acceleration scheme being proposed^[Reference Tajima and Dawson^273].

Work then started on providing VULCAN with ultra-short-pulse capability in the early 1990s. The CPA technique was invented in 1985 by Strickland and Mourou^[Reference Strickland and Mourou^50]. Its first implementation on VULCAN converted TAW into a single beam short pulse system with dedicated front end, initially home produced in collaboration with academia: Imperial College London, University of St Andrews and University of Southampton. The system commenced operations at 8 TW^[Reference Danson, Barzanti, Chang, Damerell, Edwards, Hancock, Hutchinson, Key, Luan, Mahadeo, Mercer, Norreys, Pepler, Rodkiss, Ross, Smith, Smith, Taday, Toner, Wigmore, Winstone, Wyatt and Zhou^274] as the pulse duration was limited to >2 ps, but gradually the system was upgraded generating 40 TW and ultimately 100 TW^[Reference Danson, Collier, Barzanti, Damerell, Edwards, Hutchinson, Key, Neely, Norreys, Pepler, Ross, Taday, Trentleman, Walsh, Winstone and Wyatt^275]. One unique feature of the system was a single passed grating compressor, with the first grating in air, largely driven by cost issues. The system worked well and produced a wealth of pioneering publications in laser–plasma interactions^[Reference Norreys, Zepf, Moustaizis, Fews, Zhang, Lee, Bakarezos, Danson, Dyson, Gibbon, Loukakos, Neely, Walsh, Wark and Dangor^22, Reference Bell, Beg, Chang, Dangor, Danson, Edwards, Fews, Hutchinson, Luan, Lee, Norreys, Smith, Taday and Zhou^61, Reference Modena, Najmudin, Dangor, Clayton, Marsh, Joshi, Malka, Darrow, Danson, Neely and Walsh^62, Reference Fews, Norreys, Beg, Bell, Dangor, Danson, Lee and Rose^276].

In 1996 the CLF developed the pioneering technique of OPCPA for use on high-power lasers. The initial concept was first demonstrated by Dubietis et al., at Vilnius University, Lithuania, in 1992^[Reference Dubietis, Jonusauskas and Piskarskas^277]. but the concept was first postulated for high-power applications within the CLF by Ian Ross et al. ^[Reference Ross, Matousek, Towrie, Langley and Collier^278] for large-aperture systems, to generate powers in excess of 10 PW and focused intensities >10²³ W·cm^-2.

In this technique the frequency-doubled light from a high-energy Nd:glass laser facility is transferred to a chirped short-pulse laser via parametric amplification in typically BBO, LBO or KDP crystals, depending on beam aperture. The first terawatt OPCPA laser was demonstrated on VULCAN by Ross et al. in 2000^[Reference Ross, Collier, Matousek, Danson, Neely, Allott, Pepler, Hernandez-Gomez and Osvay^279]. The OPCPA technique is now recognized as the primary method of generating multi-petawatt laser systems and it has been implemented across the world.

VULCAN Petawatt^[Reference Danson, Brummitt, Clarke, Collier, Fell, Frackiewicz, Hancock, Hawkes, Hernandez-Gomez, Holligan, Hutchinson, Kidd, Lester, Musgrave, Neely, Neville, Norreys, Pepler, Reason, Shaikh, Winstone, Wyatt and Wyborn^280] came on-line in 2003 operating to a separate target area with high-energy petawatt capability (500 J in 500 fs). The petawatt output compressor, in the newly constructed target area, is shown in Figure 32 during final commissioning. OPCPA was used, for the first time worldwide, as a front-end driver for the system^[Reference Collier, Hernandez-Gomez, Ross, Matousek, Danson and Walczak^281]. A later upgrade saw the addition of a synchronized single long-pulse beamline^[Reference Musgrave, Boyle, Carroll, Clarke, Heathcote, Galimberti, Green, Neely, Notley, Parry, Shaikh, Winstone, Pepler, Kidd, Hernandez-Gomez and Collier^282]. VULCAN Petawatt was recognized as the ‘highest intensity focused laser in the world’ by the Guinness Book of World Records in 2004^[283] and was a scientific feature in the 2005 edition^[284].

Figure 32

The VULCAN Petawatt target area during final commissioning with Andy Frackiewicz on the platform operating the crane and Trevor Winstone guiding from the ground in 2003. (Picture courtesy of STFC.)

Experimental breakthroughs on VULCAN were not only limited to ultra-short pulse interactions. In 2014, in a campaign led by Professor Gianluca Gregori, University of Oxford, VULCAN was used to simulate turbulent amplification of cosmological magnetic fields in laboratory experiments, creating conditions similar to those generated during the formation of galaxies. The experiment became one of the top-10 scientific breakthroughs of the year as listed by Physics World ^[Reference Meinecke, Doyle, Miniati, Bell, Bingham, Crowston, Drake, Fatenejad, Koenig, Kuramitsu, Kuranz, Lamb, Lee, MacDonald, Murphy, Park, Pelka, Ravasio, Sakawa, Schekochihin, Scopatz, Tzeferacos, Wan, Woolsey, Yurchak, Reville and Gregori^285].

The VULCAN Petawatt target area is currently undergoing an upgrade with the addition of a petawatt-class OPCPA-based beamline delivering pulses with 30 J and 30 fs with a centre wavelength of 880 nm^[Reference Musgrave, Blake, Boyle, Clarke, Collier, Galimberti, Hernandez-Gomez, Pepler, Oliviera, Shaikh, Winstone, Wyatt and Wyborn^286]. A new laser area was created that housed a front-end based on a DPSSL-pumped picosecond OPCPA scheme, whereby the output from a Ti:sapphire oscillator is amplified to the millijoule level in LBO. These pulses are then stretched to 3 ns before undergoing further stages of amplification in LBO, the final stage employing one of the VULCAN long-pulse beamlines as a pump laser. The pulses are then compressed in the target area and focused into the same target chamber as the existing petawatt beamline.

The VULCAN 2020 upgrade project is a proposal to increase the peak power of VULCAN to 20 PW delivering 400 J in 20 fs, and to significantly enhance its long-pulse capability. This developed from an initial proposal for 10 PW operation^[Reference Hernandez-Gomez, Blake, Chekhlov, Clarke, Dunne, Galimberti, Hancock, Heathcote, Holligan, Lyachev, Matousek, Musgrave, Neely, Norreys, Ross, Tang, Winstone, Wyborn and Collier^287]. The facility would include a new target area for interactions at extremely high intensities. The peak power would be increased by the installation of an OPCPA beamline using DKDP crystals pumped by two dedicated 1.5 kJ Nd:glass lasers. The long-pulse provision would be increased by the use of additional 208 mm aperture Nd:glass amplifiers, increasing the output energy of each of the six long-pulse beams to ∼2 kJ per beam.

Lasers for science facility. The Ultra-Violet Radiation Facility (UVRF) began operations in April 1982, led by Fergus O’Neill, to establish programmes in photochemistry, photobiology, resonance Raman spectroscopy, physics and micromachining. The first operational laser was a commercial rare gas halide laser using KrF operating at 249 nm producing 1 J at 25 Hz. The first photobiology experiment used UV spectroscopy to obtain structural information of proteins and enzymes in solution. The UVRF became the Lasers Support Facility (LSF) in 1985, after user demand began to exceed available time. This incorporated various laboratories and introduced the LLP whereby universities could borrow lasers for use at their own institutes.

The LSF laboratories were initially intended for picosecond, nanosecond and X-ray research. The use and names of the laboratories changed significantly over the years as the programme of work altered. In the 1990s two new laboratories were added: the Femtosecond Laboratory (later moved building to become the Astra laser facility); and the X-ray Laboratory.

The LLP officially began on 1 May 1985. It was funded by EPSRC, operated a range of state-of-the-art excimer and dye lasers, and provided national support for a wide range of research programmes in chemistry, physics, life science, materials and engineering. The lasers were loaned to UK academics for use in their home institutions for periods of 3–6 months. By the time of its closure in 2016, the LLP had supported 76 departments in 49 institutes across the UK and Europe.

In 1995, the LSF was rebranded as the ‘Lasers for Science Facility’ to reflect its mission to enhance the use of lasers throughout all scientific disciplines. The LSF was then led by Dr. Tony Parker and continued in the role until 2011.

By 2003 the LSF comprised the world-leading Time Resolved Resonance Raman (TR³) Spectroscopy Facility^[Reference Kwok, Ma, Matousek, Parker, Phillips, Toner, Towrie and Umapathy^288], the Picosecond Infra-Red Absorption and Transient Excitation (PIRATE) project^[Reference Towrie, Grills, Dyer, Weinstein, Matousek, Barton, Bailey, Subramaniam, Kwok, Ma, Phillips, Parker and George^289], the Laser Microscopy Laboratory, the Laser Tweezers Facility^[Reference Aveyard, Binks, Clint, Fletcher, Paunov, Annesley, Botchway, Parker, Ward and Burgess^290] and the LLP. The PIRATE laser was funded in 1999, by the EPSRC, to revolutionize tunable lasers for studying chemical and biological events on the picosecond time scale and is shown in Figure 33 being adjusted by Mike Towrie.

Figure 33

Mike Towrie lining-up PIRATE in 2000. (Picture courtesy of STFC.)

In 2005 the CLF developed and patented the technique spatially offset Raman spectroscopy (SORS) to look beneath the surface of a material to reveal its properties^[Reference Matousek, Clark, Draper, Morris, Goodship, Everall, Towrie, Finney and Parker^291].

The Artemis system, opened in 2008 under the leadership of Dr. Emma Springate, provides ultra-short pulses in the XUV through the process of laser–plasma HHG, for the study of electron dynamics and structure in materials, via techniques such as time-resolved photoemission spectroscopy.

In 2009 the Ultra laser system^[Reference Greetham, Burgos, Cao, Clark, Codd, Farrow, George, Kogimtzis, Matousek, Parker, Pollard, Robinson, Xin and Towrie^292] opened for users under the leadership of Professor Mike Towrie, developing on the technology used in the PIRATE laser system. This was funded by STFC and BBSRC, representing a change from a chemical focus to looking at more complex biological molecules, proteins and DNA, furthering the capability to study structure and function of molecules in the more biologically relevant solution phase.

In 2019 Artemis was upgraded with the addition of a 100 kHz IR OPCPA system and relocated to the Research Complex at Harwell (RCaH), in a joint project with the Ultra group. This opened up new opportunities in ultra-fast Raman and unique hybrid narrowband/broadband capabilities, such as surface sum frequency generation and multidimensional spectroscopy techniques. The Artemis system opened in 2008 providing ultra-short pulses in the XUV, allowing the creation of movies of electrons moving within molecules.

The Octopus system (Optics Clustered to OutPut Unique Solutions) opened in 2010 under the leadership of Professor Marisa Martin-Fernandez, providing a world-leading laser microscopy imaging facility focusing on bioscience, giving access to a wide range of multicolour laser-light sources giving unprecedented flexibility to combine multiple beams, multiple colours and timing capabilities.

In 2010/2011 the LSF moved into purpose-built facilities in the newly established RCaH, encouraging cross-disciplinary research.

The Astra/Gemini titanium sapphire laser facility. Astra was an ultra-short-pulse CPA laser using titanium-doped sapphire (Ti:sapphire) as its gain medium operating at 800 nm. It was built to take advantage of the CPA technique and to ensure that CLF was at the forefront of short-pulse plasma physics. It started operations in 1997. Ti:sapphire, with its extremely broad bandwidth, can produce pulses of duration <30 fs, a factor of 10 shorter than Nd:glass. Thus, although it cannot produce the same energies as Nd:glass, it can produce equivalent or even greater power and, hence, intensities onto a target.

Two target areas were in operation: one used for experiments on photo-physics and photo-chemistry, and the other for generating high harmonics and experiments on electron acceleration.

In 2004 an international team, led by researchers from Imperial College London, conducted a landmark experiment using Astra to demonstrate the world’s first ever monoenergetic, high-quality electron beam from a laser interaction in a gas jet. The team, led by Stuart Mangles, are shown during the campaign in Figure 34. The results were published in Nature, and appeared as a front cover feature, under the heading ‘Dream beam’^[Reference Mangles, Murphy, Najmudin, Thomas, Collier, Dangor, Divall, Foster, Gallacher, Hooker, Jaroszynski, Langley, Mori, Norreys, Tsung, Viskup, Walton and Krushelnick^82].

Figure 34

Alec Thomas, Chris Murphy and Stuart Mangles (foreground), experimental lead, in Astra Target Area 2 during the monoenergetic electron beam experiment in 2004. (Picture courtesy of STFC.)

Following a three-year programme of construction, in 2007 Astra was upgraded to become the front-end of Gemini^[Reference Hooker, Collier, Chekhlov, Clarke, Divall, Ertel, Foster, Hancock, Hawkes, Holligan, Langley, Lester, Neely, Parry and Wyborn^293]. The building in which Astra was housed required modification to accommodate a new target area (TA3) and associated control room, a new laser area (LA3) directly above the TA3 bunker, and to convert the old Titania Target Area Control Room into what is now the Services Area.

Gemini, which opened to users in 2013 under the leadership of Dr. Rajeev Pattathil, has two ultra-high-power beamlines, each delivering 15 J in 30 fs pulses at 800 nm, giving 500 TW beams to target, generating focused intensities >10²¹ W·cm^–2. Routine high-contrast operation can be achieved with the use of a double plasma mirror assembly within the target chamber.

The Centre for Advanced Laser Technology. In 2011, the Centre for Advanced Laser Technology and Applications (CALTA) was created, led by Chris Edwards, to deliver societal, scientific and economic impact from developments in the CLF, principally through development of the CLF’s DiPOLE laser architecture. DiPOLE is a diode-pumped, solid-state laser system delivering high energy, high repetition rate with high wall-plug efficiency. This established and proven concept is based on a cryogenically cooled multi-slab amplifier head operating at 140 K.

DiPOLE laser technology development started in 2012 with the production of a prototype laser designed to operate at 10 Hz pulse repetition rate, generating 10.8 J of energy in a 10 ns pulse at 1029.5 nm. The system was pumped by 48 J of diode energy at 940 nm, corresponding to an optical-to-optical conversion efficiency of 22.5%. The DiPOLE concept was applied to a two-amplifier head design, resulting in 100 J of laser radiation within a 10 ns pulse at a 10 Hz repetition rate, in a design known as D100.

The first laser was delivered to HiLASE, Dolni Brezany, Czech Republic, in 2014^[Reference Mason, Divoký, Ertel, Pilař, Butcher, Hanuš, Banerjee, Phillips, Smith, De Vido, Lucianetti, Hernandez-Gomez, Mocek and Collier^294]. A second laser is currently being commissioned at the Euro-XFEL facility, Hamburg, Germany^[Reference Mason, Banerjee, Smith, Butcher, Phillips, Höppner, Möller, Ertel, De Vido, Hollingham, Norton, Tomlinson, Zata, Merchan, Hooker, Tyldesley, Toncian, Hernandez-Gomez, Edwards and Collier^295]. Recent advances have demonstrated 150 J pulse energy output at 1 Hz^[Reference Phillips, Banerjee, Ertel, Mason, Smith, Butcher, De Vido, Edwards, Hernandez-Gomez and Collier^296], a world record for diode-pumped technology, and stable 10 Hz operation of 77% conversion efficiency for frequency doubling using a type-I phase-matched lithium triborate crystal^[Reference Banerjee, Mason, Phillips, Smith, Butcher, Spear, De Vido, Quinn, Clarke, Ertel, Hernandez-Gomez, Edwards and Collier^297].

The Extreme Photonics Applications Centre. In 2020 the CLF began construction of the Extreme Photonics Applications Centre (EPAC), under the leadership of EPAC Technical Director and CLF HPL division leader Cristina Hernandez-Gomez. The ground-breaking ceremony, held on 11 February 2020, was attended by Professor Donna Strickland, winner of the Nobel Prize in Physics 2018, and MP Chris Skidmore (then UK Government Science Minister). EPAC will enable experiments using a 10 Hz petawatt laser for academic, industry and security users and will impact on a wide range of research fields and industry sectors, from fundamental discovery science to inspection tools for high-value manufacturing.

The facility will use the CLF’s patented diode-pumped laser technology, DiPOLE, utilizing the D100 laser to pump a Ti:sapphire amplifier with an OPCPA front end, delivering 30 J in 30 fs at 10 Hz. EPAC will be an ecosystem for innovation by bringing together a diverse user community and delivering a wide range of capabilities, mainly exploiting the huge range of applications enabled by laser-driven plasma accelerators. The facility will enable rapid, high-resolution X-ray computed tomography imaging for advanced manufacturing industries and for biological, materials, environmental and cultural heritage communities, along with innovative inspection technologies for defence and advanced plasma-based accelerator physics concepts and experimental exploration of quantum electrodynamic phenomena.

3.2.3 CLF support facilities

As a facility provider for the UK and international plasma physics user community it is vital to provide comprehensive user support in all activities including travel and accommodation, experimental preparation, operational support and post experimental analysis. In this section, we highlight the support provided by the Target Fabrication, Plasma Physics and Engineering Groups.

Target Fabrication Group. From its early days in the 1970s the CLF had a Target Preparation Laboratory which produced the micro-targets required to support the experimental campaigns on its laser facilities. Back in the late 1970s to early 1980s, the majority of targets were spherical glass spheres, typically 70–100 μm in diameter with a glass wall thickness of about 1 μm. The spheres were individually selected and hand-mounted onto 4 μm carbon fibres which were bonded to pulled glass stalks attached to magnets, designed to be mated with the mounting system inside the target interaction chamber. Most were given a flash-coating of aluminium to aid alignment in the target chamber. Even in those early days, thin foil targets were in demand. Formvar and carbon thin-foil strips mounted on an angled brass holder were cut using a home-made CO₂ laser housed in the Target Preparation Laboratory. Figure 35 shows the Micro-Assembly area of the Target Fabrication Laboratory in 1982.

Figure 35

Beryl Child, standing, and Sarah Hallewell in the CLF’s Target Preparation Micro-Assembly Laboratory in 1982. (Picture courtesy of STFC.)

Deep UV (excimer laser) lithography and micromachining systems were developed at RAL in 1985–1996. The deep UV optics required for this were designed in-house and manufactured by UK optics companies such as IC Optical Systems Ltd (ICOS). Early work concentrated on deep UV lithography projection systems with reduction ratios of up to 10:1. Today laser micromachining, which can trace its path back to this early work, is an integral part of CLF’s Target Fabrication Group and is used every day for target-making as well as other micro-engineering applications.

The Target Fabrication Group’s capabilities were extended in 2008 and have recently been expanded again to house a state-of-the-art deep reactive ion etcher for MEMS (microelectromechanical systems) target fabrication, along with new laser micromachining laboratories which house femtosecond, nanosecond and excimer laser machining operated by the CLF’s spin-out company Scitech Precision Ltd.

The present-day CLF has a world-class Target Fabrication Laboratory capable of producing a huge variety of solid micro-targets. Micro-components are produced using a range of techniques such as micromachining, thin film coating and wafer-based manufacturing (to name but a few). These are then assembled, and micro-targets are measured using a range of high-accuracy techniques. Accurate metrology is critical to the understanding of the interaction physics on experiments. Scitech Precision Ltd supplies micro-targets commercially for use on many international laser facilities worldwide.

Plasma Physics Group. The Plasma Physics Group formally started in 2001 but grew out of the CLF Theory Group which had been in place since the founding of the CLF in support of the user community. The early group consisted of internationally renowned theorists in Tony Bell, Roger Evans and Dennis Nicholas; with Steve Rose joining in 1983. The group started a tradition of having a user meeting just before Christmas held at the Coserner’s House in Abingdon, Oxon. This initially small annual meeting has grown over the years to become the Christmas Meeting of the UK High Power Laser Community now attracting over 170 attendees from largely the UK plasma physics community.

Peter Norreys took over the reins of the newly formed Plasma Physics Group following the departure of Steve Rose in 2001. Alex Robinson joined in 2005 eventually taking over the leadership of the group in 2015. The group still exists to support the users of the CLF and to explore new avenues of research through its world-class theoretical and computational plasma physics research and simulations. The CLF has used the SCARF resource (an STFC high-performance computing cluster), and, over a number of years, has invested in a number of its own clusters that are part of the SCARF infrastructure, with the largest (to date) being SCARF-Derevolutionibus.

Engineering Division. The Engineering Division provides engineering support for experiments, from design and manufacture to safety systems and diagnostic development. The process starts with the experimental design team that lays out the experiment and designs any bespoke engineering components necessary to facilitate the experiment. The CLF mechanical workshop, CLF electrical workshop and target area technicians manufacture, assemble and install all aspects of the experiment in advance of the experiment’s allocated time slot. During the experiment, the whole team is on hand to deal with experimental changes and unexpected developments.

The engineering team operates across all of the CLF’s facilities and is responsible for ensuring the safe operation of systems required for all laser areas, target areas and R&D labs. The CLF interlock systems ensure the safety of CLF staff and visiting scientists by controlling access to areas and the operation of lasers and shutters. The engineering team installs and maintains all the services required, including the vacuum systems, gas delivery, cooling water, gas detection, power supplies, drive system, control system and communication. They also support and develop the mechanical and electrical systems for all areas to improve the capability and efficiency of the whole facility. These development projects range from developing new diagnostics to setting up new development laboratories.

3.2.4 Other CLF programmes

European Laser Facility. In 1989 the CLF proposed the construction of a 100 kJ European Laser Facility (ELF). The facility was based on either the Nd:glass or KrF technologies being developed at the CLF. The more than £100 million estimated cost was, in the case of KrF^[298], an extrapolation from where the CLF development had reached. For Nd:glass^[299] the estimate was based on the project costs of relevant international facilities, including the Omega and NOVA facilities in the USA and the Gekko XII facility in Japan. Unfortunately, the proposal did not go forward, but the programme developed in-house expertise in the design and costing of much larger systems, essential for what was to come, and gave further international credibility to the CLF.

Laserlab-Europe. The CLF has been one of the leading laser laboratories in Europe engaging with the EU through its mobility and access programmes. This began in the 1980s, initially with a pilot programme in the FP2 (Framework Programme), and then individual contracts under FP3 and FP4 (the Framework Programmes were each four-year research and development mobility initiatives). This enabled numerous research groups from across Europe to access the facilities at the CLF, including VULCAN, Astra and the Lasers for Science Facility. These access experiments were not only of benefit to the visiting scientists but quickly established collaborations with both groups in UK universities and researchers at the CLF.

The EU introduced a more coordinated approach under FP5 in 2001 with the establishment of LASERNET. This was a management consortium of all the laser facility access providers across Europe, while still maintaining individual contracts with each facility. As the largest provider of access to its lasers, the CLF was able to take a leading role in the development of the consortium. This was important as in the next phase, during FP6 the EU established I3s (Integrated Infrastructure Initiatives), resulting in a single access contract with all LASERNET partners. Laserlab-Europe^[261] was therefore established in 2004 with 17 infrastructures from nine countries. Under these new arrangements the research portfolio increased to not only cover access but joint research activities (JRAs) and training.

For over 30 years there have been EU funded access arrangements to the CLF facilities for European researchers. This initiated many of the individual collaborations which would last, in many cases, a lifetime. The relationships developed between the CLF and its European researchers also gave rise to their participation in its annual meetings and provided an opportunity for European members of the CLF experimental selection panels. This has partly been responsible for developing an integrated European research community amongst the users of its laser facilities with numerous joint initiatives outside of EU funding.

Announced in 2019, the EU is funding an unprecedented fifth phase of the Laserlab-Europe contract. The initiative has significantly grown and now has 35 partners from 18 member countries, including the UK’s University of Strathclyde and Orion at AWE as members/associate members. It provides the access, networking and training opportunities, to plasma physicists as well as biologists, chemists and material scientists, treating lasers in a very similar way to any other conventional beamline user facility, such as synchrotrons or particle accelerators.

The High Power Laser Energy Research Facility. The High Power Laser Energy Research Facility (HiPER)^[300] was a pan-European research project co-ordinated from the UK by the CLF. The initial idea came from the CLF’s Peter Norreys and championed by the then CLF Director, Henry Hutchinson. The project was then coordinated by the new CLF Director Mike Dunne and managed by Chris Edwards. HiPER brought together 26 partners from 10 EU countries to demonstrate the technical and economic viability of laser fusion for the production of energy. The project was accepted on to the EU ESFRI (European Strategy Forum on Research Infrastructures)^[301] Large Scale Facilities Roadmap in January 2007. At the time it was believed that NIF^[302] would demonstrate ignition in a laser-driven fuel pellet in 2010. HiPER was designed to move forward from this landmark demonstration. In an initial three-year preparatory phase funded by the EU the project studied the feasibility of laser-driven fusion, looking at ignition schemes, laser development, diagnostics and target design. A conceptual artists impression of the HiPER facility is shown in Figure 36. Following the issues with NIF the project eventually came to an end in 2015 following the last dedicated SPIE workshop in Prague. The HiPER project provided a unifying force for the laser, theoretical plasma and experimental plasma physics communities leaving a lasting legacy for the project.

Figure 36

Artists impression of the High Power Laser Energy Research Facility – HiPER. (Picture courtesy of STFC.)

3.2.5 CLF spin-out companies

An important aspect of the CLF’s work has been its contribution to the UK economy through the establishment of spin-out companies exploiting its developments. The following companies established themselves in the marketplace.

• • Exitech was the first company to spin out of the CLF in 1984 to manufacture specialized laser micromachining systems. It grew quickly and established itself as an important supplier of these systems.

• • Colsicoat Ltd established in the mid-1980s specializing in optical coatings and phase plates for focal spot smoothing techniques.

• • Oxford Framestores developed image-capture technology.

• • LaserThor was spun out of the CLF in 1999 in conjunction with the rail industry to provide a high-tech approach to the cleaning of railway tracks.

• • L3 Technology Ltd in 2001 to develop medical applications for an optical spectroscopic technique that can be used to tell good cholesterol from bad.

• • Cobalt Light Systems spun out in 2006 to find new applications for SORS, developing scanners and explosive detection at airports and product lines for the pharmaceutical industry. It was acquired by Agilent Technologies in 2017, now operating as part of Agilent’s global centre for Raman spectroscopy, located on Harwell Campus.

• • Scitech Precision was formed in 2009 supplying bespoke micro-targets for high-energy/power laser facilities globally.

3.2.6 Summary of activities at the CLF

The CLF was established to provide a centralized large-scale laser facility for laser–plasma interaction research. This remit has significantly broadened through its history to provide facilities covering photochemistry, photobiology and micromachining. It has always been at the leading edge of facility provision and development, with its experimental programmes gaining international recognition. It has been highly proactive, working with its university partners, industry and the international community. Through spin-out companies and the work of CALTA the CLF has also made significant contributions to the UK economy.

3.3.1 The early years

Laser development began at AWRE (later to be shortened to AWE) Aldermaston in 1962^[Reference Hunt^303, Reference Flynn^304]. A High Power Laser Group was set-up led by Richard Fitch, an expert in pulsed power. Although there was no immediate goal, it was thought that developing devices which could generate high power would have some relevance to the AWRE programme. An Applied Optics Group under Ken Coleman was tasked with investigating some of the special properties of laser radiation. The operation of a ruby laser was soon realized with a technique, exploited by the group, using a rotating mirror to produce Q-switching, multi-nanosecond giant pulse operation. AWRE had developed an ultra-fast camera using a high-speed rotating mirror and using it in the laser became an early success in the programme. Also at this time, the Analysis Section was using a ruby laser for vaporizing samples for analysis.

It was clear at an early stage that the construction of large lasers using ruby would have severe technological limitations. Fortunately, in 1961, laser action was discovered in neodymium-doped glass by E. Snitzer, Hughes Research Laboratories^[Reference Snitzer^305]. A number of companies, including Chance-Pilkington in the UK, were able to produce high-quality doped glass. This was to become an important development in the construction of high-power lasers.

This was an exciting time in the laboratory with many of the necessary technologies (glass blowing, high-voltage capacitors, flashlamps, etc.) being close at hand. Several different types of gas laser were constructed (argon, nitrogen, carbon dioxide) as well as liquid lasers (selenium oxychloride and a rhodamine 6G dye laser). Using the technique called ‘mode-locking’^[Reference Hargrove, Fork and Pollack^306], the generation of picosecond laser pulses was also achieved. The first demonstration of a laser-triggered spark gap was made at AWRE.

Using entirely theoretical criteria, Ron Wilson (AWRE) proposed a mercury laser operating at 546 nm. Although a laser was constructed at AWRE it was left to a US laboratory to make the system operational. In 1963, a CO high-repetition-rate laser was constructed giving an output at 607 nm and operated at 50 Hz. In parallel with this experimental work, computer techniques were being developed to understand laser behaviour and to predict performance. In 1973, an internal paper was published ‘Simulation of laser action and iterative solution of laser problems using a computer’^[Reference Hunt^307]. The use of similar programs became vital in the development of high-power lasers.

An unusual type of laser was discovered by David Hunt. It was a laser that used the nitrogen and carbon dioxide in human breath to operate^[Reference Hunt^308]. Colloquially it was called the ‘breathalaser’ and is shown in Figure 37 being optimized by David Hunt. It was demonstrated in a television programme called The Frontiers of Science in 1969. The compere was Professor Oliver Heavens (University of York) and it was his breath that was used in the demonstration.

Figure 37

Dave Hunt with the ‘breathalaser’. (Picture courtesy of AWE.)

In the Applied Optics Group, Mike Wall, John Turpin and Ivor Pearce used lasers for applications in holography and interferometry. One of their first applications was pressure vessel testing, observing the deformations on the vessel during operations.

There were a number of industrial collaborations in these early days: with the National Physical Laboratory (NPL; Ian Ross et al., who soon moved to the CLF); Pockels cell development with EOD Ltd; transfer of flashlamp technology from AWRE to Noblelight; and image converter cameras commercialized by Hadland (later Hadland Photonics). In the mid-1960s AWRE aided Culham in the construction of a 1 GW, 10 ns ruby laser for plasma diagnostics.

In 1965 all laser work at AWRE was transferred to a single building. This included development of a 1 kJ Nd:glass laser with a pulse width of 6 ms. This was the highest-energy laser in the UK at the time. Development also started on CO₂ gas lasers in the mid-1960s, with a 5 W system built.

Following a revision of work at AWRE in 1965, a diversification programme was initiated. This was a conscious national effort by the UK Government’s Ministry of Technology, under Anthony Wedgwood Benn, to bring the resources and expertise of the aerospace and nuclear industries to bear on the civilian economy. It was thought that the national R&D effort had been too closely focused on defence, and the rest of the economy needed a kick-start, so the whole programme had top-level political support and related to Harold Wilson’s ‘white heat’ revolution. It was therefore a vote of confidence in AWRE’s scientific excellence. The opportunity was taken to look at medical applications of lasers including clearing atheroma deposits in arteries, cutting heart tissue and drilling holes in teeth.

Ken Coleman took over group when Fitch left to go to the US. In 1968, high-power laser research stopped at AWRE Aldermaston as it was believed there was a lack of relevance to the core programme. The high-power Nd:glass laser was transferred to Foulness, Essex, at that time part of AWRE, where Peter King and Hugh McPherson were responsible for its operation and development. The laser initially produced an output of 1 GW and was later developed to produce 10 GW.

In 1970 AWRE set up the Laser-Fusion Study Group under Alan Fraser to coordinate theoretical and experimental work on lasers to initiate fusion reactions. A two-year programme was established at AWRE to identify the most promising laser for fusion research. On 9 May 1972, at the 7th International Quantum Electronics Conference in Montreal, Dr. Edward Teller disclosed for the first time the previously classified work on laser fusion taking place at the Lawrence Livermore Laboratory^[Reference Teller^309]. Later that year John Nuckolls et al., from Livermore, published this work in the open literature^[Reference Nuckolls, Wood, Thiessen and Zimmerman^310]. This changed the whole dynamic of how, and with whom, discussions on fusion could happen.

3.3.2 Early 1970s: AWRE’s three-pronged approach

The importance of laser-driven indirect drive for HEDP experiments was recognized at AWRE in 1971^[Reference Thomas^311]. The paper describes how experiments on high-power laser systems can be used to measure less well-understood aspects of radiation hydrodynamics and material properties. Hence, many of the techniques used for HEDP relevant to stockpile stewardship were largely developed at AWRE/AWE by Brian Thomas et al. for the study of materials in extreme conditions. This was reinforced as the world moved towards the era of the Comprehensive Test Ban Treaty (CTBT).

The continued investment in high-power lasers was justified as part of the UK’s commitment to be a responsible nuclear weapons state, continuing safety and stockpile stewardship. There was an awareness in the US of lasers being used for stockpile stewardship but their programme through the 1970s and 1980s concentrated on the fusion aspect of laser interactions. There was therefore a requirement for AWRE to have its own large-scale laser capability and so it developed a three-pronged approach to finding a suitable laser, with CO₂ and Nd:glass laser development in-house, and iodine laser development under contract at the University of Manchester.

The AWRE was transferred to the MoD in 1973, and later merged with the Directorate of Atomic Weapons Factories (Royal Ordnance Factories (ROF)) at Burghfield and Cardiff to form the Atomic Weapons Establishment (AWE) on 1 September 1987.

Carbon dioxide laser. CO₂ lasers are electrically discharged pumped gas lasers delivering pulses at a wavelength of 10.6 μm. One of the main advantages of these lasers is their relatively high efficiencies, of several per cent.

With many years’ experience of AWRE developing CO₂ lasers at beginning of 1974 they constructed a 200 MW CO₂ system (10 J in 80 ns). This was operated by Frank Morgan and used for laser plasma experiments led by Brian Thomas, primarily foil studies, relevant to the behaviour of thin fusion shell targets during compression and the development of instabilities.

A second CO₂ laser with output of 1 GW (specified at 1 J in 1 ns) was designed and commissioned in 1975, led by Peter Blyth and later aided by David Hull. This was a master oscillator power amplifier (MOPA) design with a well-defined low-energy pulse generated in an oscillator and amplified in a series of four amplifiers. The system’s detailed operational parameters were characterized, and it demonstrated performance of ~1.5 GW at both 1 and 20 ns^[Reference Hull and Blyth^312].

At this time, there were no central laser facilities available to the academic user community. One of its most senior members, Professor Malcolm Haines, Imperial College London, requested time on the AWRE lasers, which led to Joe Kilkenny and PhD student Malcolm White performing interaction experiments on the 1 GW system in 1975. The laser was reconfigured with an AWE designed laser-triggered spark gap and a Pockels cell switch which would allow synchronization of the CO₂ laser to a Q-switched diagnostic ruby laser. The campaign led to high-level publication in Physical Review Letters by Gray et al. in 1977^[Reference Gray, Kilkenny, White, Blyth and Hull^313].

Following developments at Los Alamos, there was a project to build a much larger CO₂ laser amplifier which would be e-beam pumped to boost the output of the laser to 50 J. An initial design was developed and commissioned by Ted Thornton, Terry Taylor and Steve Davidson, although technical issues limited its effectiveness. An alternative amplifier was designed and built by Peter Blyth working with Charlie Martin; affectionally known as the ‘father of pulsed power’^[314]. The amplifier with an aperture of ~20 cm worked extremely well, but was never fully integrated into the laser.

Iodine laser. An iodine laser is a flashlamp-pumped gas laser operating at an output wavelength of 1.315 μm. For AWRE’s programme, the iodine laser development was contracted out to the University of Manchester under the stewardship of Professor Terry King. A system was constructed delivering 30 J in 1 ns. The work proved very productive with over 50 journal papers published; see, for example, Ref. [Reference Baker and King315].

The leaders in the field at this time were the group at Garching, Germany, who developed the Asterix III laser which was producing 300 J in 1 ns; Asterix was later transferred to Prague to become PALS (Prague Asterix Laser System)^[Reference Rus, Rohlena, Skála, Králiková, Jungwirth, Ullschmied, Witte and Baumhacker^316]. This gave confidence on the scaling of these systems and the Manchester group designed an iodine system to deliver 1 kJ in 100 ps (10 TW)^[Reference Baker and King^317]. This was much higher than the value that could be delivered by Nd:glass at the time, but demonstration of shorter pulses had not happened in Manchester at this point.

Nd:glass laser. The well-established Nd:glass laser at Foulness was moved back to AWRE in 1972. Hugh McPherson and Peter King came from Foulness to help set it up in the tunnel in building N78 (known as the N78 laser). The group expanded with Edward (Ted) Thornton, a pulsed power engineer. When Hugh and Peter returned to Foulness Robin Pitman took over the laser joined by laser scientists Clive Ireland, Tom Bett and later Peter Blyth. The system eventually became known as MERLIN.

The laser was a seven-stage Nd:glass laser system with initially a final rod amplifier diameter of 64 mm. There were no spatial filters at that time: the beam simply expanded from a pinhole through a series of rod amplifiers of increasing aperture: 10, 16, 23, 32, 45, and 64 mm. The system was designed to operate at output levels up to 100 GW with a pulse duration of 1 ns or 25–100 ps duration from a mode-locked Nd:YAG oscillator. One unique feature of the laser was a superconducting magnet Faraday rotator generating a DC field of ~4 T with an aperture of 45 mm developed by Thor Cryogenics, Oxford.

The laser was first used for experiments in 1975 operating at 10 GW (40 J in 1 ns) by Frank Morgan and David Hull, pioneering new techniques for equation of state measurements. The MERLIN target chamber is shown in Figure 38. The system realized its full design performance of 100 GW in the following year. The final amplifiers suffered from filamentation as non-linear effects were only just being discovered at that time, and therefore a 90 mm rod was added to reduce the peak fluence^[Reference Bett, Flynn, Ireland and Pitman^318].

Figure 38

The MERLIN target chamber. (Photo courtesy of AWE.)

Choosing the way forward. In the mid-1970s the Superintendent for Fusion and Optics (SFO) evaluated what would be required from a future laser system. It was decided that a new larger laser would be required in late 1970s with an estimation that 10 times more energy/power would be needed, i.e., a 1 TW system. Tom Bett^[Reference Bett^319] assessed the suitability of all potential laser systems for laser fusion including excimer, gas, molecular, solid-state, liquid and dye lasers. The conclusion was that the only realistic candidates for fusion were Nd:glass, pulsed CO₂ and the iodine gas laser, consistent with AWRE’s three-pronged programme which was already in place.

An SFO team was tasked with identifying how the higher-power laser requirements could be met. The team of McCormick, Hunt, Turpin and Bett, held discussions with the US laboratories and with the broader community at the 10th and 11th European Conferences on Laser Interaction with Matter held in 1976 in Palaiseau, France, and in 1977 in Oxford, UK, respectively. The SFO was soon to be split into two to become the Superintendent Laser Facilities (SLF) under Pat Flynn and the Superintendent Plasma Experiments (SPE) under Norman Daly.

There was a very active programme on CO₂ development at Los Alamos with a system designed to deliver 2.5 kJ in 1 ns from two beams. A separate system delivering 250 J was already operational. Flynn et al. ^[Reference Flynn, Hunt and McCormick^320] identified that although CO₂ systems had higher efficiencies, the longer wavelength would be an issue in target interactions. Thus, even though CO₂ was the more advanced programme at AWRE, the decision was made to concentrate on the shorter-wavelength options of both iodine and Nd:glass.

The iodine laser was identified as a viable larger-scale facility but there were still some unresolved design issues, including sub-nanosecond operation. If these could be resolved it was seen as a faster route to a 10 TW, cost-effective laser system.

The largest Nd:glass laser being developed at the time was the 10 kJ, 500 ps Shiva multi-beam system at Lawrence Livermore Laboratory. A 270 J laser, Cyclops, at <200 ps was already operational. The advantage of Nd:glass was that it was an energy storage medium and it could be scaled up to large aperture with good optical quality. The technical risk was low because the technology was well advanced, as demonstrated by the existing facilities. Livermore also prepared to allow AWRE access to its laser component designs^[Reference Flynn, Hunt and McCormick^320]. It was therefore decided to proceed with the Nd:glass option and curtail the iodine programme.

3.3.3 The HELEN laser facility

The new laser facility, later to be called HELEN, was specified as a 1 TW two-beam Nd:glass laser. The energy specification of 500 J per beam would require the use of disc amplifiers, as developed in the USA for use in the Shiva laser facility that was under construction at the Lawrence Livermore Laboratory. It would be impractical for AWRE to design their own disc amplifiers, but there were restrictions on information exchange directly from LLNL. There were two possible ways forward: the supply of custom amplifiers from General Electric; or using those of Livermore design using a private company, ILC (International Lamp Corporation), as a subcontractor. General Electric had delivered disc amplifiers to KMS Fusion, USA, and CILAS, France, for use in their laser systems, but at the time they were untested. Their amplifiers were of lower gain than that of the Livermore design, which was an important consideration, and hence the only viable option was to go with ILC. A contract was therefore placed with them in 1977 to construct a two-beamline facility to an AWRE design, initially called the AFL-1 laser (Aldermaston Fusion Laser).

The transfer of information to ILC went well, and the delivery and installation of the components to AWRE started in 1978 but, there were many details of the Shiva components and design that were not captured in the drawings. The contract with ILC stipulated that it was their responsibility to commission HELEN to low-power operation, but it soon became very clear that this small company was not going to be able to build and install the major laser components for HELEN without assistance. In early 1979, Livermore was given permission by DoE/DoD to send personnel to assist ILC. Two senior LLNL staff, Bill Martin and Larry Berkbigler were seconded to AWRE for six weeks in early May 1979. Bill had experience of the development of Shiva’s front-end systems and amplifiers. In addition, the AWRE laser team were also allowed to get involved, with Ivor Pearce looking after the front-end oscillator, Robin Pitman for system alignment and Peter Blyth for beam characterization and laser diagnostics.

In 1978 it was announced that Her Majesty the Queen would visit AWRE to open the new laser facility and to recognize the 21st anniversary of the 1958 defence agreement between the USA and UK. The Queen and Duke of Edinburgh visited on 29 June 1979 to formally open HELEN. A remote-control room was set up to initiate a firing of the laser by the Queen. TV images from the HELEN control room were relayed to this ceremonial area. AWRE and Livermore staff worked very long hours and succeeded in getting HELEN to work end to end on several occasions and one of these was a successful commissioning target shot that was captured on video. As it happened, due to a fault with HELEN, instead of the live pictures being used during the ceremony this video back-up had to be deployed to save the day. Thus, when the Queen pressed the button, the video was played. The Queen and Duke of Edinburgh had a tour of the HELEN laser, as shown in Figure 39 in the Target Hall with John Weale, Head of the Radiation Physics Department. The Queen was then presented with an encapsulated laser amplifier rod.

Figure 39

Queen Elizabeth II is shown the HELEN target chamber by John Weale, Head of Radiation Physics Department, to mark the formal opening of the facility in 1979. (Picture courtesy of AWE.)

Following the departures of Robin Pitman, Clive Ireland and Peter Blyth, Colin Danson joined the group in 1980 fresh from an undergraduate Physics degree at Nottingham University. There was a steep learning curve for the newly assembled young team since they had no hands-on experience with the electronics or optics of the laser system. The HELEN Laser Hall is pictured during commissioning in Figure 40. The early section of the laser was redesigned by Clive Ireland of AWE. Bill Martin, one of the Livermore scientists, returned to assist the group and the laser was eventually made operational. Electrical interference caused by an earth loop had been a major stumbling block to commissioning efforts. Target shots to support AWE’s experimental programme were first time in 1981. At this time HELEN operated with pulse lengths of 100–300 ps, delivering 100–200 J per beam at 1064 nm.

Figure 40

The HELEN laser during commissioning. (Picture courtesy of AWE.)

Electrical noise problems were largely solved by moving the pulse generation system to a separate dedicated area in 1983–1984, plus an upgrading of the control electronics. Around the same time, harmonic conversion in KDP of the beam outputs (from 1064 to 532 nm) was implemented. The ~30% reduction in delivered energy was more than offset by increased absorption at the target. The next significant enhancement in 1989–1990 involved the conversion from Nd:silicate to Nd:phosphate glass, increasing of the main beam aperture from 200 to 300 mm and increasing of the nominal output to 500 J in 1 ns at 527 nm. A couple of years later a third ‘backlighter’ beamline providing 100 J in 100 ps, fed by a separate synchronized oscillator, was also commissioned. It was realized that X-ray backlighting was a powerful diagnostic tool that required a main interaction beam onto the target and a separate beam to a second target generating a synchronized X-ray source. Figure 41 shows a photograph of the HELEN Target Hall under self-illumination from the scattered laser light following frequency conversion of the laser beams to the green (527 nm).

Figure 41

The HELEN target area with self-illumination from the green light produced when the laser beams are frequency doubled. (Picture courtesy of AWE.)

Continuing the theme of incremental improvements, the late 1980s/early 1990s saw the arrival of distributed phase plates for focal spot smoothing, initially binary random DPPs but then moving to phase zone plates (PZPs). These concentrate more energy in the central pattern^[Reference Bett, Danson, Jinks, Pepler, Ross and Stevenson^321] and for these a UK patent was subsequently awarded to staff from AWE and RAL.

HELEN saw further upgrades with the provision of a front-end whose technology originated from LLNL transferred through AWE staff secondments to work on Beamlet. The system was commissioned in 1996 featuring: flexible pulse shaping (100 ps–5 ns); a diode-pumped oscillator; fibre-based integrated optics amplitude modulators; and a ring-regenerative amplification stage. A multi-pass amplifier design^[Reference Norman, Andrew, Bett, Clifford, England, Hopps, Parker, Porter and Stevenson^322] of HELEN was implemented in 2000.

Owing to a requirement for greater efficiency a new configuration, multi-pass, was planned for the NIF and LMJ laser facilities. This was realized on HELEN with the availability of laser components, in particular 50 mm aperture rod and 200 mm aperture disc amplifiers, following the closure of the NOVA laser facility at LLNL. The architecture contains fewer components with benefits in reduced cost and maintenance, and increased system availability. This configuration would later be used for the Orion long-pulse (nanosecond) beamlines. The HELEN multi-pass project was delivered by an in-house team, led by Mike Norman, highlighting the build-up of high-power laser expertise at AWRE over the previous 20 years.

There was awareness of the work at RAL on the implementation of CPA on VULCAN. Steve Rose was Department Head at the time and was key in promoting an ultra-short-pulse beamline on HELEN. This led to the conversion of the HELEN long-pulse backlighter beam to sub-picosecond operation during 2001–2004. The baseline performance was >100 TW (70 J in 500 fs, f/3 focusing), limited only by the compressor grating size^[Reference Hopps, Nolan, Girling, Kopec and Harvey^323]. Frequency doubling of the output was also implemented, providing greatly enhanced pulse contrast on target. This capability proved critical for laser–plasma investigations (e.g., opacity measurements), driving its inclusion on Orion. Subsequently, the operation of HELEN for several years in long and short pulse mode underpinned the development of several of the key experimental techniques later implemented on Orion. A particular example was the ‘multi-target mount’, which allowed precise independent alignment of different target elements for long and short pulses.

HELEN operations were finally halted in April 2009 after ~30 years of successful operations, in order to free up resources, both staff and cleanroom space, for the construction and commissioning of Orion. Many components of HELEN were then recycled, for use in the construction of facilities at Imperial College London, the CLF at RAL and SLAC in the USA. The large-aperture Faraday rotators from HELEN were used on the Orion facility.

3.3.4 The Orion laser facility

A successor to HELEN had been planned for many years. Numerous variants were considered, ranging from maximizing the use of the existing facility by adding extra HELEN-like beams, up to a new building housing 32 NIF-like multi-pass beams. An alternative proposal was to pay for an additional target chamber on the NIF at LLNL, USA, in a project called TAURUS (Target Area for UK Research in US). The key step, in the early 2000s, driven by then Head of Plasma Physics, Steve Rose, with the support of Brian Thomas and others, was to define more precisely the range of conditions required for the various experiments of interest at AWE and the laser parameters required to deliver them. The advent of ultra-high-power lasers^[Reference Danson, Haefner, Bromage, Butcher, Chanteloup, Chowdhury, Galvanauskas, Gizzi, Hein, Hillier, Hopps, Kato, Khazanov, Kodama, Korn, Li, Li, Limpert, Ma, Nam, Neely, Papadopoulos, Penman, Qian, Rocca, Shaykin, Siders, Spindloe, Szatmári, Trines, Zhu, Zhu and Zuegel^141], using the CPA technique^[Reference Strickland and Mourou^50], presented an opportunity to design a unique (and affordable) facility able to reach relevant conditions for many experiments as well as being complementary to larger more conventional lasers, offering scope for collaboration. This was the genesis of Orion whose name originates from Orion the hunter’s association with Taurus the bull.

Orion was uniquely designed to deliver 10 ‘long-pulse’ beams, each delivering 500 J at 3ω (351 nm) in a nanosecond pulse and two ‘short pulse’ beams each delivering a petawatt in the IR^[Reference Hopps, Danson, Duffield, Egan, Elsmere, Girling, Harvey, Hillier, Norman, Parker, Treadwell, Winter and Bett^324, Reference Hopps, Oades, Andrew, Brown, Cooper, Danson, Daykin, Duffield, Edwards, Egan, Elsmere, Gales, Girling, Gumbrell, Harvey, Hillier, Hoarty, Horsfield, James, Leatherland, Masoero, Meadowcroft, Norman, Parker, Rothman, Rubery, Treadwell, Winter and Bett^325]. The Orion Laser Hall is shown in Figure 42. This dual pulse design enabled compression of a target with the long-pulse beams, target heating with one short pulse and diagnosis with second short pulse. This combination enabled conditions on target to be achieved that were similar to those achieved on very much larger lasers such as the NIF, albeit on smaller targets.

Figure 42

The Orion Laser Hall showing the long pulse beamlines on the left and the two petawatt beamlines on the right. (Picture courtesy of AWE.)

AWE conducted a feasibility study of the Orion baseline design in 2003–2004 and the project was given the go-ahead by the MoD in 2005. The official ground-breaking ceremony to start construction took place in July 2006. The Orion project broke new ground at AWE as it was the first large capital project in over 20 years. The formal project, included the building, installation and initial commissioning demonstration phase, was completed in 2010 and was delivered on-time and on budget (£170 million). Full system commissioning was completed a year later. Project completion, which included a demonstration of achieving relevant conditions^[Reference Hoarty, Allan, James, Brown, Hobbs, Hill, Harris, Morton, Brookes, Shepherd, Dunn, Chen, Marley, Beiersdorfer, Chung, Lee, Brown and Emig^326] on target, was achieved in March 2013.

Orion is housed in a custom multi-storey building with a 100 m × 60 m footprint supported on 300 sleeved piles for stability. It is by far the largest laser system constructed within the UK. Over 70% of the building volume has high-quality air-conditioned cleanrooms, with two major halls housing the laser and target systems. The Orion laser system was designed in-house with the construction project managed by Jacobs Engineering overseen on the AWE side by Tom Bett with his laser team from HELEN critically involved in the laser system construction and subsequent commissioning. Key staff included Nick Hopps, Mike Norman and Colin Danson becoming the first shot directors enabling completion of the formal project milestone and subsequent transitioning to operations. The project involved several hundred people and requires a team of 20 or so scientists, engineers and technicians to operate the system.

The transition from HELEN to Orion operations was a step change in complexity. On the practical scale, HELEN was a two-dimensional system where alignment was mostly a hands-on process with easily accessible components. The shift to a vast three-dimensional structure required a culture change where everything is motorized and viewed remotely. Staff who had previously spent most of their day within the laser hall were now doing the same job behind a desk. To manage all of this, the scale of the control systems required meant that the engineering and support teams had to be substantially larger.

The added complexity also required an increased level of oversight and control of operations to ensure that the right beams were delivered to target at the right time, safely. To facilitate this, Orion moved to a ‘Shot Director’ model (this was trialled on HELEN in its last year of operation), where one person was responsible for all aspects of a laser shot and had the final say on whether the shot would go ahead. What had previously been ‘quick simple jobs’ now require careful planning to ensure that any work is de-conflicted with the operations of the rest of the facility.

Orion has been operating continually since it began full operations in April 2013. The versatility of the facility means that it has been used as a tool to study a huge range of phenomena from simulating the interactions of binary stars, high-temperature/pressure opacity measurements, proton heating and imaging, studying the equations of state of materials in extreme conditions, to driving impulses through large (1”) samples. Figure 43 is a photograph of the Orion target chamber showing the vacuum propagation of one of the petawatt beamlines into the chamber on the left, a long-pulse beamline top right, and one of the six TIM (Ten Inch Manipulator) diagnostic insertion systems lower right.

Figure 43

The Orion 4 m diameter target chamber. (Picture courtesy of AWE.)

From the outset the UK’s MoD planned that up to 15% of Orion’s operational time should be made available to the UK academic community. Time is allocated on the facility using a competitive peer review process managed by the CLF through their High Power Laser Facility Access Panel, which also prioritizes access to VULCAN and Gemini. The first two campaigns, scheduled in 2013, produced research papers of the highest calibre being published in the Nature family of journals^[Reference Cross, Gregori, Foster, Graham, Bonnet-Bidaud, Busschaert, Charpentier, Danson, Doyle, Drake, Fyrth, Gumbrell, Koenig, Krauland, Kuranz, Loupias, Michaut, Mouchet, Patankar, Skidmore, Spindloe, Tubman, Woolsey, Yurchak and Falize^327, Reference Higginbotham, Stubley, Comley, Eggert, Foster, Kalantar, McGonegle, Patel, Peacock, Rothman, Smith, Suggit and Wark^328].

Orion has been progressively upgraded through its life to meet user demands. The pulse duration on the long pulse beamlines has been extended from the original 5 ns up to 10 ns with the option to delay beamlines relative to each other to further extend the effective pulse duration as seen by the target. The contrast of the short pulse beamlines has been enhanced through a series of upgrades: the introduction of a picosecond optical parametric amplifier (OPA) to the front-end and frequency doubling of the output of one of the short-pulse beamlines. This allowed Orion to generate ~200 TW pulses with a contrast of ~10^18[Reference Hillier, Elsmere, Girling, Hopps, Hussey, Parker, Treadwell, Winter and Bett^329], the highest contrast demonstrated on any facility worldwide. An upgrade to the frequency-doubled system has since been implemented, with larger-aperture crystals and a double-aperture geometry to deliver ~400 TW^[Reference Parker, Danson, Egan, Elsmere, Girling, Harvey, Hillier, Hussey, Masoero, McLoughlin, Penman, Treadwell, Winter and Hopps^330].

3.3.5 Target fabrication

To support the laser–plasma programme, AWRE/AWE has instigated, and then continuously developed, the capability for providing the required micro-scale targets. To deliver viable data on the conditions of the experiment, targets must be carefully designed, fabricated and characterized. The size of target components and assemblies ranges from millimetres down to tens of micrometres and they can be made of a wide array of materials, from precision-machined gold enclosures (termed hohlraums), to low-density foams and aerogels, metal and polymer coatings, laser-machined foils and laser-machined strips. Any components and assemblies that are created must also be measured to high precision, so that the experimenters can properly interpret their results. This requires a sophisticated suite of characterization equipment, from coordinate measuring machines to interferometers, micro-balances, scanning electron microscopes and micro X-ray computed tomography (CT) scanners.

It was quickly evident that target fabrication required a multi-skilled science and engineering workforce, cooperating closely across disciplines to help solve complex problems, often at the edge of the possible. AWE target fabrication has sustained this over several decades, supporting programmes on the MERLIN, HELEN and Orion lasers as well as collaborative experiments outside the UK. The success of AWE target fabrication continues to rely on the exceptional skills developed by its teams, while steadily augmenting this with increasingly sophisticated technology to enable uplifts in target complexity and enhanced diagnosis of the finished targets.

Over the lifetime of the AWE programme, target fabrication has been based in several locations, occasionally benefitting from being co-located with its main customer facility. Having been alongside HELEN, from around 2000 to 2012, with the opening of Orion, target fabrication was again remote from the laser. However, in 2019, target fabrication was relocated into the Orion building. This had the added benefit of improving integration of some capabilities (e.g., precision machining) whilst also providing modern workspaces with improved environmental control. At the same time the opportunity has been taken for another phase of equipment renewal, meaning that the target fabrication team is well placed to support the laser–plasma programme into the next decade and beyond. Figure 44 shows the target assembly area with a target for NIF operations under construction.

Figure 44

NIF target being assembled at AWE using video coordinate measuring machine supported assembly techniques. (Picture courtesy of AWE.)

3.3.6 Summary of activities at AWE

AWRE/AWE recognized the potential for lasers soon after their invention and explored development initially for wide application to varied work within the establishment but very early on, the ability of high power lasers to generate hot dense matter was identified and significant effort put into this field, particularly close to one of the main objectives of the establishment. The laboratory over the last 40 plus years developed and built several generations of high power systems, building enduring relationships with national laboratories, academia and industry both within the UK and internationally in the field of high power lasers, optics and plasma interaction experiments. This ongoing programme continues today with its current world class facility Orion.

The expertise developed within AWE has been used extensively over the years in both active collaboration and in an advisory capacity. Many AWE scientists, both laser and plasma physicists, have been on secondment at LLNL in the US, contributing to their programme. Recently, many have also been members of international boards, for example: the ELI-Beamlines facility, Czech Republic^[331]; Laser Megajoule, France^[Reference Ebrardt and Chaput^332]; and Laserlab-Europe^[261].

4.1.1 Isle of Man

The Isle of Man established itself as a hotspot for precision optics manufacturing, with a global reputation. Technical Optics Ltd was established in 1973 by brothers Mike and David Lunt. They first set up business in North Wales but moved to the Isle of Man as there were attractive start-up grants for small companies to diversify the island’s economy. They were taken aback when arriving in the Isle of Man to have the Tynwald (the Isle of Man’s Parliament) Member for the Economy meet them and help them unpack their van. Their board room had a large statement image of a range of optics they produced shown in Figure 48.

Figure 48

Photograph that graced the Boardroom of Technical Optics for many years. Courtesy of Helmut Kessler, Manx Precision Optics, where the picture now resides.

J. Bibby Ltd bought out Technical Optics in the early 1990s and when in 1995 Bibby acquired Melles Griot, Technical Optics was renamed Melles Griot Technical Optics to mark its integration into the Melles Griot Group. CVI bought Technical Optics out in 2000, renaming it CVI Technical Optics. In 2011 it became part of the IDEX Group. It finally closed as CVI Technical Optics in early 2014 after nearly 40 years of trading.

Quality Laser Optics (QLO) was set up in 1992 by Gary Thomas, who had led the Nd:phosphate glass slab polishing at Technical Optics. Previously, from 1981 to 1987, he had gained significant experience at Zygo Corporation, USA, working on the largest optics used on any laser systems worldwide: mirrors up to 1 m diameter and phosphate disks at 46 cm clear aperture for the US, French and Japanese lasers. QLO was sold to CVI Technical Optics in 2006 and integrated into their operation. Gary emerged again to set up Island Optics Ltd in 2013^[339]. Island Optics Ltd remains as a precision optics manufacturing company specializing in precision flats such as mirrors, windows, beamsplitters and polarizers.

In 1997, a new company was to spin out of Technical Optics, SLS Optics Ltd^[340], specializing in the manufacture of Fabry–Pérot etalons, precision laser optics and thin film coatings. The name SLS refers to its founders Lionel Skillicorn, Mike Lunt and Jim Schwarz.

Solarscope^[341] was set up in the early 2000s by Ken Huggett, who was in charge of the instrumentation department of Technical Optics. Ken had previously, after leaving Technical Optics in the late 1990s, worked with David Lunt at Coronado Instruments who re-located from the Isle of Man back to the US. Solarscope quickly established itself as one of the leading high-quality manufacturers of hydrogen alpha filters for solar observation. The etalon plates and coating were manufactured on the Isle of Man, first by Technical Optics, then by QLO and SLS Optics, drawing on the vast experience present in the Isle of Man for these very high-end products.

In 2013 a further company was to establish itself in the Isle of Man, Manx Precision Optics Ltd^[342]. Its founder was Helmut Kessler, who had started at Technical Optics in 1995 as a coating designer and later became their General Manager. The company specializes in the manufacture of precision optics (flat and spherical) for high-power lasers, having polishing and coating facilities to produce optics up to 500 mm diameter. Since 2014, Manx Precision Optics supplied the etalons to Solarscope and when Ken Huggett retired in 2018 Helmut Kessler and his wife bought the company to continue the manufacture of hydrogen alpha filters in the Isle of Man. Solarscope is now operating from a laboratory within the Manx Precision Optics building.

4.1.2 Rugby, Warwickshire

Rugby, Warwickshire, established itself as a world centre for the manufacture of solid-state lasers. The story started in 1964 when the Associated Electrical Industries (AEI) Central Research Laboratories were consolidated in Rugby in purpose-built facilities^[Reference Marshall and Williams^343]. Their laser development group was to employ several people who would become major players in the story of high-power lasers in Rugby: Jim Wright, Ron Burbeck and Paul Sarkies. There they developed the first Nd:YAG lasers for military guidance applications.

Jim Wright^[344], on leaving University in 1962, was awarded a Civil Service research fellowship to work on lasers at the Signals Research and Development Establishment (SRDE) in Christchurch. Here, he developed the first Q-switched Nd:glass lasers in the UK. He then joined AEI to concentrate on developing laser technology for applications rather than pure research.

In 1967, when GEC acquired AEI^[Reference Clayton and Algar^345] they moved the laser development work to Wembley, London. Jim, Ron and several other colleagues decided against the move and formed a branch of Laser Associates (Rugby), in 1968, to manufacture the first commercial Nd:YAG lasers in the UK. Laser Associates Ltd was started in Slough in January 1967, by Dillon Harris and colleagues who had left G&E Bradley, a subsidiary of Lucas, to develop lasers^[Reference Clutterbuck^346]. Ted Payne, later founder of Laser Lines Ltd, joined Laser Associates in 1969. Laser Associates established itself as one of the world’s leading laser manufacturers and even grew its own ruby crystals. However, concerns about the management of Laser Associates led Jim Wright and Ron Burbeck to resign and form JK Lasers Ltd at the beginning of 1972. Laser Associates, Rugby, was to be wound up in the same year and taken over by Ferranti.

JK Lasers specialized in the production of solid-state laser systems. The company first launched a range of pulsed lasers using ruby, Nd:YAG and glass laser rods. This was followed by the MS-Series of Nd:YAG laser systems that were designed for industrial welding, cutting and drilling applications.

The main task in those early years was to identify materials processing applications for which pulsed Nd:YAG lasers provided a competitive advantage or benefit, either as a replacement technology or as an enabling technology to allow designs and industrial processes that would otherwise not be possible. The company also started to develop overseas markets as it opened up offices and support centres across mainland Europe. In 1978, JK Lasers won the Queens Award for Export Achievement. The staff of JK Lasers were photographed (see Figure 49), outside their Somers Road premises in the late 1970s.

Figure 49

The staff of JK Lasers outside their premises at 23 Somers Road, Rugby in the late 1970s.

Throughout the 1970s and into the 1980s, JK Lasers worked collaboratively with end users to pioneer the development of numerous applications including the precision spot welding of TV electron guns and components, the seam welding of heart pacemaker cans (the lower average powers of pulsed laser technology allowing the can to be welded without damaging the delicate electronics inside) and the drilling of aircraft nozzle guide vanes and combustion chamber rings.

In July 1982 there were 100 employees in JK Lasers when they merged with Lumonics of Canada to form one of the (then) largest laser companies in the world. The merger was mutually beneficial with Lumonics manufacturing CO₂, excimer and dye lasers, whereas JK Lasers produced solid-state lasers. Lumonics represented the UK products into Canada and the USA, and JK Lasers represented the Canadian products into Europe which worked very well. The JK Lasers division of Lumonics moved from Somers Road and in 1985 it opened a purpose-built facility in Cosford Lane, Rugby.

Within Lumonics, Jim Wright continued to champion the development of the industrial laser business. In 1986, the company launched the JK700 Series of pulsed Nd:YAG lasers, the first truly industrial lasers that gained wide acceptance in the aerospace, automotive and electronic industries.

As well as developing the laser source, Lumonics provided a range of standard and bespoke laser processing systems that were often customized to a particular application. During the 1980s and 1990s, the company also developed a range of fibre-optic beam delivery systems which extended the practical application of lasers within industry by allowing the laser source to either be time shared between multiple work stations within a manufacturing facility, or by beam sharing to allow simultaneous welding, for example, in the attachment of telecommunication fibre-optic cables to laser diodes while maintaining their precise alignment. Fibre delivery also enabled remote processing to be carried out within the nuclear industry.

Jim Wright left the company in 1988 and Sumitomo Heavy Industries (SHI) of Japan bought Lumonics in the same year. Lumonics continued to develop pulsed Nd:YAG lasers across a range of powers, introducing the first 1 kW industrial laser product, and in 1990 the company won the Queens Award for Technological Achievement. It participated in various collaborative programmes to advance Nd:YAG laser materials processing capability and also extended its geographical reach into East and South East Asian markets.

As part of these developments Neal Croxford and Tony Hoult demonstrated welding and cutting at powers over 2 kW under a UK Eureka project led by Clive Ireland, producing welds over 25 mm deep in steel and over 10 mm deep in copper for the first time. This led to the development of 2 kW industrial lasers used for a variety of applications including those within the automotive industry.

During its long spell as a major force in the UK laser industry, JK Lasers and then Lumonics grew and nurtured a lot of strong teams and highly skilled individuals. Some went on to establish other laser companies, while others went on to become major players elsewhere in the market.

In 1999, SHI sold shares to General Scanning Incorporated (GSI) of Boston, MA, USA, to form GSI Group Laser Division. In 2012 GSI changed the name back to JK Lasers^[347]. In April 2015 GSI sold its JK Lasers subsidiary to SPI Lasers, part of the TRUMPF Group. All products were rebranded with the SPI logo, essentially ending the JK brand. SPI^[348] was established in 1999 as a spin-out from the University of Southampton’s ORC specializing in fibre lasers, becoming part of the TRUMPF Group in 2008. In 2018 SPI expanded their laser manufacturing capability in Rugby where they still operate today.

In 1997, InnoLas UK^[349] was formed to buy out the scientific product lines of Lumonics/JK Lasers/GSI. The founders were Bill Brown (ex JK, Lumonics, Brown & James), Dave James (ex JK, Lumonics, Brown & James), Reinhard Kelnberger (ex JK, Lumonics and InnoLas GmbH) and Janet Hull (ex JK & Lumonics). InnoLas UK continues to be a leading UK-based laser manufacturer, renowned for developing innovative solid-state laser equipment and technology for industrial and scientific users. Applications range from drilling and cutting of aerospace metals through to welding, holography, optical damage measurements and plasma diagnostics.

Paul Sarkies worked with Jim Wright and Ron Burbeck at AEI but when they went to Laser Associates, he left and went to Sheffield for a PhD working on laser glass. Paul re-joined Jim Wright at JK Lasers in 1975, then broke away to found Spectron Laser Systems in 1981. Spectron specialized in Q-switched lamp pumped scientific, medical and precision industrial processing. In 1997 Spectron was sold to Laser Industries Ltd, an Israeli company specializing in the supply of medical laser equipment. Spectron was taken over by GSI Lumonics in 2003, effectively bringing Spectron and JK Lasers back together.

Litron Lasers Ltd was set-up by Paul Sarkies, with his son Julian Sarkies as first Director, in 1997. The company pioneered commercial photodiode energy monitors as initially they were not allowed to compete with Spectron in selling lasers. In the meantime, they were developing a technology base of solid-state lasers for manufacturing. Litron’s first laser products were launched in 2002 and these have developed into a set of standard models and configurations including high-energy pulsed lasers, both flashlamp and diode pumped, for science and industry. Litron continues to be run by Paul’s three sons^[350].

Elforlight was established in early 1997 in Daventry by Keith Oakes, ex Laser Lines Ltd, and Simon Jenny, ex Spectron Laser Systems. They specialize in DPSSLs^[351]. They originally were IE Optomech and did work with the University of St Andrews. Uniphase was so impressed with the microchip laser work that they bought IE Optomech. Keith and Simon then set up Elforlight.

The legacy of the long history of laser innovation and manufacturing in Rugby is that it remains as a centre of excellence in lasers with many of the companies highlighted still trading. Other companies include: JEH Lasers Ltd^[352] established in 2019 by Janet Hull (shown in Figure 50 maintaining an old JK Lasers Nd:YAG system) who has many years’ experience designing, building, testing and servicing solid-state lasers in Rugby; and MSS Lasers^[353] providing CO₂ laser system build and service.

Figure 50

Janet Hull, JEH Lasers, maintaining a JK Lasers Nd:YAG mode locked dye system in 2020 at the Space Geodesy Group, Herstmonceux, East Sussex. Parts of the laser date back to the late 1970s, it was heavily modified in the early 1980s and is still operational.

Many laser-based manufacturing companies across the local area owe their existence to the manufacture of lasers in Rugby including DP2000 Ltd formed in 2003^[354] using lasers for cutting and welding and Precision Laser Processing Ltd (PLP)^[355], established in 1994. PLP was formerly called The Laser Job Shop Ltd. They use high-power CO₂ and YAG lasers for applications in precision manufacture for the aerospace, nuclear, automotive, medical and other industrial sectors, for laser drilling, cutting, welding and parts fabrication. PLP came out of Brown & James Ltd, a job shop started by Bill Brown and Dave James, of JK Lasers/Lumonics. They sold the company to Bob Ghavami and Graham Lucas, who were both also ex JK Lasers/Lumonics.

Aside from providing many hi-tech employment opportunities in the area for decades, one of the biggest contributions of Rugby lasers’ heritage is in aerospace blade drilling. This is used by Rolls Royce Aerospace in their production of jet engines, to improve the efficiency of the engine to the benefit of us all.

4.1.3 St Asaph, Wales

There is a significant cluster of optics and photonics companies in North Wales, centred around St Asaph. This cluster now totals about 100 companies which are within a thirty-mile radius of St Asaph and which have total revenues of over £1 billion. The cluster had its origins when Pilkington decided to move its glass manufacturing operations to St Asaph in the 1950s, which established the core focus of the cluster and brought in many suppliers and users of glass products to the area. Pilkington moved away from St Asaph in 2008, following a takeover by NSG, Japan, but crucially many of the supply chain and the skilled workforce remained in the region, and this expertise has continued to seed and grow the cluster.

Currently the largest company in the cluster is Qioptiq^[356] which designs and manufactures photonic products for applications in defence and aerospace, and it is now part of Excelitas Technologies. Other notable companies include: Tyco Electronics^[357]; Leader Optec^[358] specializing in advanced fibre-optic systems; Kent Periscopes^[359] producing vision systems for military applications; Ultra Precision Structured Surfaces Ltd^[360] using nanometre machining to produce Fresnel lenses and diffraction gratings; Laser Micromachining Ltd^[361] featured later in this section; and Phoenix Optical Technologies Ltd^[362], which produces precision optics.

Ferranti through to Leonardo in Edinburgh

Ferranti Defence Systems Ltd (FDSL) was part of Ferranti plc, a company that could trace its history back to 1885. It had a track record of significant innovation including the UK’s first commercial power station and among the world’s first commercial computers. Ferranti came to Edinburgh in 1943 and established a site at Crewe Toll to manufacture a gyro-stabilized gun sight (known as the Mark IIC) for the Spitfire and other aircraft^[Reference Ferranti^{397, 398]}, which, for the first time, gave fighter pilots a true lead angle aiming capability. This product is shown in Figures 70 and 71. The sight and its derivatives remained in manufacture for 73 years until a production run of over 60,000 units finally came to an end in 2016. After the end of WWII, the Crewe Toll site focused on the development and manufacture of radar systems and Ferranti itself grew and developed many capabilities. For example, the Valve Department had design and development sites within Edinburgh in Granton and production facilities in Dundee.

Figure 70

A Ferranti MK11C gyro-stabilized gun sight. (Picture Courtesy of Leonardo.)

Figure 71

An image of the gun sight from a Ferranti ISIS Century brochure. (Picture Courtesy of Leonardo.)

In 1963, the Valve Department in Edinburgh, led by Neil Forbes and Graham Clarke as Chief Engineer^[Reference Clarke^399], developed a HeNe laser, the Ferranti Laser Mk 1, which was the first commercial laser available in the UK. HeNe lasers, in the form of ring laser gyros for artillery pointing system are still manufactured at Crewe Toll today. Figure 72 shows an example of the resonator from a ring laser gyro.

Figure 72

A HeNe laser resonator designed to operate as a ring laser gyro. (Picture courtesy of Leonardo.)

During the early 1960s, the RRE in Malvern developed a neodymium calcium tungstate laser which was made available to Ferranti when they won a competition to develop an experimental laser rangefinder and TV sight packaged with a gyro-stabilized mirror mechanism^[Reference Blain^400]. A related contract for the Royal Aeronautical Establishment (RAE) Farnborough won in 1968 introduced a laser spot tracker; thus was born the Laser Rangefinder and Marked Target Seeker (LRMTS) for the Jaguar and Harrier aircraft.

By this point it was clear that a different laser solution was required and Ferranti obtained a starting point by swapping their well-developed radar technology for a Nd:YAG laser from Westinghouse^[Reference Blain^400, Reference Barr^401]. One of the existing Ferranti versions of this laser is shown in Figure 73. It became very clear that this laser had limitations particularly when operated over the required temperature range. The problem was traced to the laser resonator which comprised a plane mirror and a Porro prism. As is well known this combination is, at best, only partially perturbation stable. The result was that Ferranti embarked on a recovery programme resulting in a resonator design based on crossed Porro prisms with Q-switch, a member of a class of perturbation stable resonator types successfully used in military systems^[Reference Barr^401, Reference Gould, Jacobs, Rabinowitz and Shultz^402]. In addition, the problems in Q-switching at a variable temperature had to be overcome^[Reference Heywood and Eggleston^403]. The revised design was inherently stable against any distortion of the structure, which is extremely important when trying to produce a laser that can perform reliably in harsh military environments. The Ferranti design was a real technical game-changer and it has been widely imitated across the industry.

Figure 73

The Ferranti version of the Westinghouse Nd:YAG laser acquired via a radar for laser swap in 1966. The Porro is visible on the right-hand side while the mirror is at the far end. The Nd:YAG rod and pump chamber are visible in the centre of the structure. (Picture courtesy of Leonardo.)

The LRMTS product, shown in Figures 74 and 75, first flew in 1971 and went into production in 1974. It was operational on Tornado aircraft for their entire service life, from 1979 to 2019 as well as Harrier and other aircraft.

Figure 74

Reviewing the installation of the prototype LRMTS onto the Canberra test bed at Turnhouse Airport circa March 1971. (Picture courtesy of Leonardo.)

Figure 75

The LRMTS showing the stabilized sensors. (Picture courtesy of Leonardo.)

In 1972 a derivative of the LRMTS laser was built into a man-portable laser target designator (the Laser Target Marker, Type 306). This was procured by the UK armed forces and was first used during the Falklands conflict in 1982^[Reference Ferranti^397]. RAF Harriers equipped with the LRMTS supported ground troops using a Type 306 LTM to designate a target near Port Stanley from Sapper Hill. Using a lob and toss technique, the weapon was released out of sight from the target area with high accuracy resulting from terminal guidance by the LTM. The Type 306 LTM is shown in Figure 76 and, for comparison, a modern man-portable laser designator is shown in Figure 77.

Figure 76

The Ferranti Type 306 Laser Target Marker (LTM). (Picture courtesy of Leonardo.)

Figure 77

Leonardo’s modern Type 163 laser designator during a live fire test. (Picture courtesy of Leonardo.)

By the 1980s the military laser system activities were located in a factory (actually a former biscuit factory) in Robertson Avenue, Edinburgh. The laser business was under John McLeod (who took over from Muir Ainslie) and the systems business was run by Malcolm White (who took over from Bill Blain). The whole electro-optics business was overseen by Ron Dunn. The Ferranti teams were also working with the UK and US military on other product lines including higher-power lasers, IRCM sensor-defeat systems, dazzle systems, counter and counter-counter measure systems and missile seeker heads.

In the early 1990s, Ferranti made a significant contribution to the first Gulf War. The TIALD (Thermal Imaging Airborne Laser Designator) pod was already in development as the world’s first fully stabilized airborne laser designator platform that could ‘see’ at both thermal imaging (infrared) and TV (visible) wavelengths. As the Gulf War approached, it was still a year before the formal in-service date for the system, but after accelerated proving and user training in the UK, the company rushed two demonstrator systems to the Gulf and they were fitted to Tornado aircraft operating from Tabuk airbase in Saudi Arabia. The pods were an immediate success with the RAF, demonstrating for the first time the capability to drop weapons from a safe altitude whilst achieving the 100% targeting precision that comes with laser designation. The results were regularly shown on the UK national TV news. The Defence Secretary, Tom King, briefed parliament that TIALD had made a significant contribution to the UK war effort and the Prime Minister, John Major, visited the TIALD production facility.

The two pods achieved an amazing 99.1% uptime while delivering 229 direct hits on target in just 18 days. This was achieved by ‘hot podding’ the two demonstrator units. They would be rushed off one Tornado that had just completed its mission, fitted to another and then straight back up in the air. The two TIALD pods were greatly liked by their RAF users who fondly christened them Sandra and Tracey. Sandra is currently displayed fitted to a Gulf War Tornado at the Imperial War Museum Duxford.

TIALD comprised 14 line replaceable units (modules) as shown in Figure 78. Ferranti produced the laser, the stabilized platform and was the prime contractor; GEC provided the thermal imager; and BAE Systems provided the auto-tracker. The overall system provided a stabilized platform that could stay locked onto the designated target throughout any aircraft manoeuvres, both day and night^[Reference Blain^400, Reference Barr^401]. The pod is shown fitted to a Tornado aircraft in Figure 79.

Figure 78

The TIALD internal structure. (Picture courtesy of Leonardo.)

Figure 79

TIALD mounted on a Tornado. (Picture courtesy of Leonardo.)

In 1987 Ferranti purchased International Signal and Control (ISC), a United States defence contractor and subsequently changed its name to Ferranti International plc. Unknown to Ferranti, ISC’s business involved a lot of illegal arms sales. The financial and legal difficulties that resulted finally forced Ferranti into bankruptcy in December 1993. Many of the ‘jewels in the crown’ of Ferranti including the Foxhunter (Tornado fighter) Radar and TIALD were acquired by GEC Marconi and the ownership went through further transfers to the current holders, Leonardo.

In many ways the developments involved in LRMTS and TIALD established the capabilities that are still in use in the Advanced Targeting Sector at Leonardo today. They combined a precision product, the laser, with a stabilized electro-optic platform and delivery system^[Reference Blain^400, Reference Barr^401, Reference Thomson and Proc^404, Reference Barr, MacDonald, Jeffery and Troughton^405].

From this starting point the business developed a range of products. A notable novel application was the development of IRCMs. These defend aircraft against heat seeking missiles by detecting a missile launch, tracking the missile and then neutralizing the missile using a modulated light signal to confuse the missile seeker^[Reference Thomson and Proc^404, Reference Barr, MacDonald, Jeffery and Troughton^405].

The period between the early 1990s and 2003 saw a major reduction in the employees in the defence industry, including Ferranti. The organization was taken through a number of owners and ultimately the Edinburgh activity was reduced to a single site at Crewe Toll employing 2000 people. Since 2003 the Advanced Targeting Sector has undergone a period of rapid change and expansion. This period saw continued production of IRCM systems and, starting in 2002 with the win of the laser designator contract for the F35 aircraft, a significant resurgence in the laser business.

The period following 2000 is one of the longest running periods of substantial success for innovative new products in lasers and electro-optics^[Reference Barr^401, Reference Barr, MacDonald, Jeffery and Troughton^405]. Almost entirely export led, this business has received multiple awards including Queen’s Award for Enterprise for International Trade in 2010 (both lasers and IRCM contributed) and for innovation in 2011 in the field of design and manufacture of military lasers. In 2018 an Institute of Physics Business Award was received for the development of Miysis, an advanced, compact IRCM system including an electro-optic tracker integrated with a compact and reliable mid-IR laser.

The Leonardo product range covers laser designators for the F35 Lightning II stealth multirole combat aircraft and for the AH-64 Apache attack helicopter. In addition, both US Airforce targeting pods (the Sniper pod and the Litening pod^[406]) contain laser designators designed and built in Edinburgh. A lightweight man-portable designator (one third of the mass of previous design with equivalent output) has proven a highly successful product and is exported around the world. The IRCM product range is thriving with the introduction of the Mysis DIRCM (Directed IRCM) system and also with the continued supply of pointer/tracking heads exported to the USA as part of a long-standing collaboration with Northrop Grumman Corporation.

The technologies embedded within these products^[Reference Barr^401, Reference Barr, MacDonald, Jeffery and Troughton^405] support the efficient manufacturing in high volume of the most compact and efficient examples of these products available today. The approach has been to identify new concepts and new technologies where appropriate to reduce size, weight, power and cost, often referred to as SWAP-C. The drive has been to utilize common parts where possible, but not be afraid of adding innovation to improve product discriminators. The laser in the Litening pod^[406] supports designation, range finding at two wavelengths and active imaging of objects at long range; truly it is a multifunction laser.

There are many innovative solutions embedded within the Leonardo product range. Novel features of these lasers include new perturbation stable resonator designs^[Reference Barr^401]; miniaturized electronics enabling five printed circuit cards to be replaced by a single card; the introduction of new athermal laser diode technologies and magnesium alloy chassis to enable a lightweight high-performance man-portable laser designator, as well as additively manufactured components.

Looking to the future, Leonardo is developing a beam director for directed energy applications as part of the UK Dragonfire consortium, which also involves MBDA and QinetiQ. The beam director accepts a high-power laser beam (50 kW) and accurately points the beam at a distant target^[407]. In a parallel activity Leonardo is investing in high-power fibre amplifiers optimized for military applications. The scale of these items presents a particular challenge; the beam directors of this class weigh in some two orders of magnitude heavier than our current airborne IRCM pointer trackers. The comforting fact is that the many talented engineers involved in the project and our supply chain have risen to these opportunities. A model of the Dragonfire Beam Director is shown in Figure 80.

Figure 80

A model of the Dragonfire Beam Director unveiled at DSEI 2017. (Picture courtesy of Leonardo.)

Thales Optronics (formerly Barr & Stroud)

Barr & Stroud^[Reference Moss and Russell^408] was established in Glasgow in 1888 to develop and manufacture optical rangefinders for military applications. Inevitably, upon the demonstration of the first laser in 1960, interest grew in the application of this novel technology to rangefinders. The company collaborated with Hughes to develop a rangefinder product based on the ruby laser. This became the LF1 launched in 1965^[Reference Moss and Russell^408]. Subsequently, Barr & Stroud integrated optical sights with this LRF and supplied them for installation into the Chieftain Main Battle Tank in 1969^[Reference Moss and Russell^408]. Similar tank fire control systems were supplied into many other armoured fighting vehicles. The first laser design fully completed and fielded by Pilkington Optronics (who acquired Barr & Stroud in 1977 and rebranded it as Pilkington Optronics in 1988) was a man portable laser designator and rangefinder known as LF28A in the late 1990s^[Reference Barr^409]. Pilkington Optronics also provided the laser designator for the UK Apache fleet through a ‘build to print’ arrangement with Northrop Grumman Lasers.

Thomson CSF acquired 50% of Pilkington Optronics in 1991, another 30% in 1994 and took full control in 2000. The company later rebranded as Thales Optronics Ltd.

Subsequent developments included, in 2001, the acquisition of Avimo, a well-known manufacturer of vehicle sights, which introduced flashlamp pumped Er:glass lasers to their portfolio. These were used in laser rangefinding applications that required eye-safe operation. An upgraded LF28A laser designator incorporating target location capabilities and also the diode-pumped Er:glass rangefinder modules was marketed under the product name TYR.

British Aerospace PLC

The Sowerby Research Centre (SRC), Bristol, was formed in 1983 as an offshoot of the British Aerospace (BAe) Dynamics Group, the guided missile division of British Aerospace PLC, now known as BAE Systems PLC. It was named after James McGregor Sowerby who was the Research Director of the BAe Dynamics Group. Sowerby had the vision of a single corporate research centre for the whole BAe company and the SRC did become the corporate research centre in 1987.

In the early 1980s, SRC was carrying out research and development of pulsed TEA CO₂ lasers, producing outputs of up to a few joules at repetition rates up to a few hundred hertz. There were also technology evaluation programmes on blue–green lasers for underwater applications, as well as excimer and mercury bromide laser systems.

In the late 1980s and early 1990s, SRC joined the EU-funded Eureka EU213 ‘Eurolaser’ project with an objective to build a 1 kW average power XeCl laser and to explore industrial applications of excimer lasers. A number of lasers were developed both in the UK and in Europe and, although none achieved the full 1 kW, all produced several hundred watts. The SRC laser itself was an impressive piece of engineering consisting of a closed loop gas circulation system, about 2.5 m by 4 m and rated at a pressure of 10 bar, see Figure 81. The laser ran at a pulse repetition rate of 2 kHz, as did the pulsed power supplies and an X-ray pre-ionizer. The interest of the Eurolaser project for SRC was potential manufacturing applications in both the military and civil aircraft markets, such as hole drilling, surface treatment and marking.

Figure 81

Eurolaser, with Trevor Bearpark (left) and Simon Scott in the foreground.

Dr. Peter Dickinson, who was leading the SRC contribution to the EU213 project left SRC in 1989 to become the Managing Director of Spectrum Technologies Ltd, a spin-off company from BAe that produces laser cable marking systems using excimer lasers. Spectrum Technologies Ltd, which is based in Bridgend South Wales, is still producing excimer cable marking systems for the aerospace and space businesses and has sold over 1000 cable marking systems in 50 different countries.

In the mid-1990s, after the Eurolaser project finished, research into pulsed gas lasers was declining. Simon Scott developed a large TEA CO₂ laser which produced 300 J output pulses, the last high-power gas laser that was developed in SRC.

In 1999, BAe merged with Marconi Electronic Syste3ms to form BAE Systems PLC. The Marconi research centres at Wembley and Great Baddow were merged with SRC to form the Advanced Technology Centre (ATC), part of BAE Systems (Operations) Ltd, which operated on several sites. In 2015 the ATC at Filton (Bristol) was closed and several members of the original Laser Devices Group transferred to MBDA UK Limited.

MBDA

In the late 1980s and early 1990s the BAe Dynamics Group was severely reduced in size, owing to the end of the Cold War. In 1996 the BAe Dynamics division was merged with Matra Defense, the French missile company, to become the company MBD. Further joining of the European missile business followed as shown in the attached figure and the company eventually became MBDA, see Figure 82. Today it is a joint venture company with shareholders BAE Systems, Airbus and Leonardo. In 2019 the company had more than 11,500 employees and a turnover of €3.7 billion. MBDA works with over 90 armed forces worldwide.

Figure 82

The origins of MBDA. (Picture courtesy of MBDA.)

MBDA has more than 30 years’ experience working on high-energy laser systems, conducting extensive research and development on a variety of programmes and related activities across Europe. These include a high-power laser system to deal with the very current threat of small agile drones. MBDA is the prime contractor for the UK’s Dragonfire DEW demonstrator programme, leading a consortium comprising QinetiQ (who makes the laser and coherent combining system), Leonardo (who makes the beam director) and BAE Systems, all working collaboratively with the DSTL.

QinetiQ

QinetiQ is a British multinational defence technology company headquartered in Farnborough, Hampshire. It has annual revenue (2020) of £1.073 billion. As a private entity, QinetiQ was created in April 2001; prior to that, it had been part of the Defence Evaluation and Research Agency (DERA), a now-defunct British government organization. While a large portion of DERA’s assets, sites and employees were transferred to QinetiQ, other elements were incorporated into the Defence Science and Technology Laboratory (DSTL), which remains in government ownership. Former DERA locations, including Farnborough, Hampshire, MoD Boscombe Down, Wiltshire, and Malvern, Worcestershire, have become key sites for QinetiQ.

In February 2006, QinetiQ was floated on the London Stock Exchange, following an inquiry by the UK’s National Audit Office. QinetiQ has completed numerous acquisitions of defence and technology-related companies, primarily those based in the United States and is a trusted supplier to the US government. It has also spun off some of its technologies into new companies, such as Omni-ID Ltd. QinetiQ is currently quoted on the FTSE 250 Index.

Prior to the acquisition, the government laboratories that became part of QinetiQ made many significant contributions, working in collaboration with the companies mentioned elsewhere in this review. For example, RAE Farnborough collaborated with GEC Ferranti in the development of the TIALD pod. SERL at Baldock had a significant role in the development of CO₂ TEA lasers.