Thanks for visiting Laser Systems Europe.

You're trying to access an editorial feature that is only available to logged in, registered users of Laser Systems Europe. Registering is completely free, so why not sign up with us?

By registering, as well as being able to browse all content on the site without further interruption, you'll also have the option to receive our magazine (multiple times a year) and our email newsletters.

A legacy in lasers

Share this on social media:

Issue: 

The LIA has introduced a set of annual awards dedicated to Professor William Maxwell Steen, a veteran and pioneer of laser technology

Professor Steen being presented with an Honorary Fellowship to the Institution of Mechanical Engineers by the institute’s president Carolyn Griffiths.

This year the Laser Institute (LIA) announced a new set of awards that it plans to confer annually to user organisations that demonstrate significant innovation in the use of lasers for advanced materials processing. Finalists and recipients of the awards will present their innovations at the International Congress on Applications of Lasers & Electro-Optics (ICALEO) on 7-10 October.

The awards will be conferred across each of the following industries: aerospace; automotive; medical devices; microelectronics; specialised manufacturing and services; research and development; life sciences; defence; academic and public sector.

 

 

They are dedicated to Professor William Maxwell Steen, a pioneer of laser materials processing research who is commonly referred to as ‘the father of laser materials processing’ in the industrial laser community. 

Steen, in addition to founding the world’s first university-based research group in laser material processing at Imperial College London in 1968, can be accredited with the invention of laser chemical vapour deposition, laser arc hybrid welding, and with his research group, the development of blown powder laser cladding and laser direct casting – processes which formed the foundation of laser additive manufacturing for metallic materials, more commonly known today as 3D printing.

He also co-founded the Association of Industrial Laser Users (AILU) in 1995 and served as its president for the first eight years. In addition, in 1997 Steen was the first European to be awarded the Arthur Schawlow Award by LIA, and at ICALEO 2008 there was a tribute session to his lifetime achievements. He has a laboratory named after him at the University of Vigo, Spain, and has received a medal from Pelacky University in Oloumouc, Czech Republic, for his pioneering work on lasers. 

Steen’s textbook Laser Material Processing – the fourth edition of which was published in 2010 – has for years been a vital source of information for students, researchers and engineers learning laser material processing. Many of Steen’s ex-students (and even their ex-students) now either run their own business, teach, or make money from laser material processing.

On hearing the announcement of the new award, Laser Systems Europe approached Steen to find out more about his many experiences exploring the realm of laser technology.

How does one go from being an industrial chemist to becoming a world-renowned expert on laser technology?

Graduating in chemical engineering from Cambridge University in 1958, it was not possible to work in laser technology yet since the laser wouldn't be invented until 1960, with industrial lasers becoming available in the 1970s. I worked as a process engineer on the development of the world’s first continuous brewing plane with APV, Crawley, and then with the Methodist Missionary Society lecturing in industrial chemistry in Burdwan University, West Bengal, where I proposed a project in fish farming using the many artificial tanks in the area. There I first heard of the existence of lasers.

On returning to UK in 1964 I was appointed lecturer at Imperial College in process metallurgy under Professor Bradshaw. I became interested in metal extraction by volatile compounds, such as chlorides, and this led to trying to make patterns by depositing metal from volatile compounds such as nickel carbonyl. I realised that the pattern was very blurred using shaped jets on hot plates and thus needed to make a shaped hot spot. The laser had been invented by this point, so I bought a glass tube with mirror mounts from Ealing Scientific, built my own power supply and I had a very unstable 5W CO2 laser on which I invented the process of Laser Chemical Vapour Deposition (LCVD), which worked but obviously needed more power. In working this up I won a contract for the first industrial fast axial flow 2kW CO2 laser from BOC developed by TWI. That gave me the most powerful university-based laser in the UK. Students and contracts flowed from this with the wide-open space for research using this entirely new form of industrial energy.

As someone who saw the introduction of laser technology into industrial materials processing, how would you say the industry's opinion of laser technology has changed over the years?

The very early years were dominated by numerous small start-up laser companies wishing to sell their lasers and compete to find useful applications at sensible prices was the main challenge (a solution looking for a problem). Cutting and welding were the only applications at that time with some curious results. Martin Adams at TWI was publishing cutting figures significantly better than everyone else; but because of the atmosphere of competition this was explained as commercial optimism. Later we came to realise he was able to cut nearly twice as fast as others because TWI had not the space for the cutting table other than in line with the laser, and the beam polarisation favoured his layout as opposed to those with transverse tables, a feature of optical energy not fully understood in those exciting times. There were many more surprises to be found as we explored this new form of energy.

For the next twenty years or so the reliability and ease of maintenance improved with most industries keeping a watching brief on what was going on. I felt at the time I could go to any company and sell the idea of a laser application as a result of this interest. In the 1990s the fibre laser arrived on the scene and the game changed. The fibre laser was smaller, required less cooling, had no alignment problems and a superb low order mode beam. To some extent it was like a dream come true. Then the physics whizz kids started making pulses shorter and shorter until we now have gigawatt pulses about 3mm long capable of blasting atoms off the surface of almost any material.

Professor Steen having been awarded the AILU Award in 2005, recognising his outstanding contribution to the industrial use of lasers in the UK. (Image: AILU)

Today, reliability and quality are taken for granted, and the only thing holding the laser back is the cost, which is rapidly coming down as more units are required. It used to be good to see the look of awe on people’s faces when you said you worked with lasers, now it is not quite indifference but certainly it is not reckoned as unusual. In summary, the opinion of industrialists today is that the laser has arrived and they are learning to live with it.

You’ve worked with lasers for cutting, welding, cladding, cleaning, marking, and pretty much every other capability of the technology! Are there any particular applications that you’ve enjoyed watching develop since your retirement in 1998? How have they changed?

There are many applications I have enjoyed working on, but additive manufacturing comes immediately to mind as something special – a game changer in the thinking of how to make things. In the 1980s Rolls Royce asked us to blow powder into the laser beam, and so we invented the laser cladding process. It worked so well it became similar to writing with metal, then one day one of my students, Mark McLean, repeatedly overlay a clad line and produced a wall. One look at that wall, particular after a metallurgical examination showed the columnar grains running up the wall instead of across the wall – as in a standard casting - showed that we had a serious new manufacturing process on our hands. Mark went onto make a stainless-steel wine glass and additive manufacturing was born.

My students all over the world were working on this promising development  Jyoti Mazumder in the USA, with the help of Chrysler, actually started one of the first companies making additive manufacturing machinery, POM. I watch with both amazement and joy at the ingenuity of what is being done with additive manufacturing and await the day that someone makes a hand-held device, either wire or powder fed, whereby the craft community can actually sculpt in reverse, i.e. build things up instead of chiselling stuff away. The precision is such that in the hands of a craftsman stunning works of art would be created. If the price is right there would be a huge market for such equipment.

Having been part of the world’s first university-based research group in laser material processing, would you say you are satisfied with how the many university laser research groups now established around the world are interacting and collaborating? Perhaps there could be more collaboration between them in order to further accelerate the innovation of laser technology?

There is quite a network of friends among my ex-students based at various institutes around the world who have a strong collaboration, while still remaining competitive, which is as it should be. 

One of my main concerns is the lack of imagination at universities. It is obvious to me and others working with lasers that they are dealing with an unusual and highly flexible form of energy available in a uniquely controllable form which can be of almost unlimited power, from milliwatts to petawatts, deliverable in times ranging from continuous to femtoseconds or even less, over a huge range of wavelengths. 

The applications of this energy range from material processing through to sensing, metrology, communications, medicine, fluorescence, interferometry, holography and x-rays. This is far more than electricity has to offer, and yet there are currently very few or no university departments dedicated to optical energy – amazing!

Could provide a good example from your career where you’ve interacted with industry successfully?

One of our most successful developments came from the work of Professor Lin Li – a past president of LIA and AILU now at Manchester University – who while exploring the possibility of sealing concrete by surface melting – for ease of cleaning, sterility etc – found that thermal cracking made this difficult. In expanding the beam to try and avoid this he found that he could explosively remove the top centimetre of the surface in reasonably large lumps. Such a simple process was taken up by British Nuclear Fuels (BNFL) for scabbling the walls of radioactive tanks prior to decommissioning. Lin Li proved the process worked and BNFL developed it further at TWI and finally used it for real in their works.

Emma Johnston being presented with the AILU Young Engineer’s Prize by John Bishop (left) and Professor Steen, who was Emma’s PhD supervisor at Liverpool University and AILU president at the time (2002). (Image: AILU)

This initiative of the LIA in instituting annual awards for the best developments coming from industry or universities should further enhance academia’s connectivity with industry, and it is very flattering that the LIA has named these awards after me!

A lot of your ex-students went on to start their own business or find success working with lasers for material processing – do you have any pearls of wisdom for those looking to start their own entrepreneurial laser journey?

It is certainly stimulating to watch my students set up a business. Those that succeed either need good financial backing and/or a great determination to win. For example, Dr John Powell started Laser Expertise in Nottingham with two friends, they were young, energetic and disciplined in work habits and finance. They spent within their budget by buying a second-hand laser and worked several years for very little return while they expanded the business of a laser job shop. John had a partner for finance, a partner for sales, and he himself had a talent for invention and much more. Together the three of them made a success of the company, which I believe now employs some 60 people.

So, if there is any pearl of wisdom, it is to have a belief in yourself and a determination to win, even when the going is tough. In the laser business the rewards can be great, with much excitement and potential novelty at any time

Navigation

Navigation

Navigation

Navigation

Navigation

Navigation