14
110
123
EPSRC 1994-2014
20
56
4-9 1994: EPSRC comes into being;
Peter Denyer starts a camera phone revolution; Stephen Salter trailblazes modern wave energy research
10-13 1995: From microwave ovens to biomedical engineering, Professor Lionel
Tarassenko’s remarkable career; Professor
Peter Bruce – batteries for tomorrow
14-19 1996: Professor Alf Adams, godfather of the internet; Professor Dame
Wendy Hall – web science pioneer
20-23 1997: The crucial science behind the world’s first supersonic car; Professor
Malcolm Greaves – oil magnate
24-27 1998: Professor Kevin Shakesheff
– regeneration man; Professor Ed Hinds – order from quantum chaos
28-31 1999: Professor Sir Mike Brady – medical imaging innovator; Unlocking the
Basic Technologies programme
32-35 2000: Plastic electronics: Professor
Sir Richard Friend and colleagues invent a new research discipline; Strategic
Partnerships: forging ever-stronger links with industry and key collaborators
36-41 2001: Makers in momentum – the
Innovative Manufacturing Research Centre programme; Professor Eric Yeatman, microelectronics maestro
42-45 2002: Professor Dave Hawkes
– 3D medical imaging for safer surgery;
Professor Sam Kingman – using microwaves to crush rocks
46-49 2003: The future is fusion: a step closer to limitless, clean and safe energy;
The SUPERGEN sustainable power generation and supply programme
50-59 2004: Wonder material graphene is first isolated; new adventures in ultrasound begin; maths giant wins major award; metamaterials pioneer is knighted
60-69 2005: Green chemistry steps up a gear; new facial recognition software becomes a Crimewatch favourite; researchers begin mapping the underworld
70-73 2006: The Silent Aircraft Initiative heralds a greener era in air travel; bacteria munch metal, get recycled, emit hydrogen
74-81 2007: A pioneering approach to prepare against earthquakes and tsunamis; beetles inspire high technologies; spin out company sells for US$500 million
82-87 2008: Four scientists tackle synthetic cells; the 1,000 mph supercar; strategic healthcare partnerships; supercomputer facility is launched
88-95 2009: Massive investments in doctoral training; the 175 mph racing car you can eat; rescuing heritage buildings; the battery-free soldier
96-101 2010: Unlocking the mysteries of antimatter; spin out sells for US$330 million; harnessing the power of pee
102-107 2011: Spin out company sells for £7.1 billion; Professor Colin Humphreys on the GaN LED revolution; the world’s first synthetic organ transplant
108-115 2012: Meet the MASER – no longer the laser’s less attractive cousin; the laundry additive that purifies the air as we walk; £60 million to encourage innovation
116-119 2013: Massive investments in manufacturing, engineering and energy; drones to monitor radiation levels
120-125 2014: Slide rules: how two doctoral students helped Lizzy Yarnold slide to gold medal victory at the Sochi
Olympics; 20 years of the Southampton
Optoelectronics Centre
126 V-signs: At last, the mystery of why birds fly in V-formation is resolved
127 EPSRC: At a glance
2

Twenty years isn’t very long in the world of research, when a discovery or breakthrough can take decades to reach its destiny. But in the
20 years since
EPSRC was formed, it’s hard not to be impressed by the incredible achievements of the inspirational scientists, engineers and mathematicians we have supported, and the world-changing research they have pioneered.
These achievements include the invention of CMOS sensors now used in most camera phones (pages 6-7); research that made possible the invention of the DVD, barcode scanners and a host of low power commercial products (pages 14-15); optical fibre technology that drives the internet
(page 124); entirely new disciplines such as plastic electronics (page 33); green chemistry for a more sustainable world
(page 61); powerful medical imaging technology, including magnetic resonance imaging (page 49); breakthroughs in physics and mathematics for the quantum world of tomorrow (pages 26, 96-97) and major advances in materials science, including the Nobel Prize-winning isolation of wonder material graphene (pages 50-53)
– all of which have helped to shape our global destinies.
Since 1994, EPSRC has invested £11 billion in pioneering research and doctoral training; supporting over 28,500 research grants and the training of 60,000 doctoral students. In addition to the £11 billion invested by EPSRC, a further £1.74 billion has been contributed by research partners from business, the charitable sector, universities, government, the charitable sector, learned societies, research councils and other funding agencies and government organisations in the UK and internationally.
This is a powerful endorsement of our founding commitments to both research excellence and to strengthening the pathways between fundamental research and its translation into products and services for the good of the UK economy and society, and for a healthier and more sustainable world.
Across our portfolio we work with around
2,800 partner organisations, and, at the last count, 45 per cent of EPSRC-supported projects were collaborative with research partners. This is part of a growing and productive dynamic that over two decades has seen a greater desire from our partners and co-investors to join in discovery and innovation; harnessing creative research from which we all benefit.
To aid this process, EPSRC has a clear set of strategies and policies, and professional staff with a comprehensive understanding of R&D issues and opportunities. People who know how to join the dots between university researchers, business and other organisations, both to enhance and deepen the body of research itself, but also to apply the fruits of research for societal and economic benefit.
Returning to those 28,500 research grants, every one of these will have undergone a rigorous process of peer review, facilitated by dedicated EPSRC staff. This would not have been possible were it not for major initiatives begun in 1994 to develop a robust yet flexible process driven by research excellence and developed through close engagement with the research community.
Our investment model has also evolved. For example, we have successfully introduced dedicated centres of excellence for the training of doctoral students; specialised centres for manufacturing and innovation; and longer, larger, multi-partner research grants – all focused on pooling resources and providing the tools and skills society and industry need for all our tomorrows.
As EPSRC enters its third decade, we will continue to work with the research community and our partners, including those from industry and government, to develop processes and initiatives that stay true to our Royal Charter of 1994, and ensure that the resources we invest keep the UK at the cutting edge of international research excellence while developing the research leaders of tomorrow.
Such is the breadth and scale of our research and training portfolio, this publication can but provide a snapshot of the people, projects and achievements from the past 20 years, and the influence many of them are now having on the world, and are already having on the future. If the past two decades are anything to go by, EPSRC’s
40th anniversary will be very special indeed.
3
EPSRC 1994-2014

1994
On April 1 1994, the
Engineering and
Physical Sciences
Research Council came into existence.
At first glance, the main difference from
EPSRC’s previous incarnation, the Science and Engineering Research Council (SERC), was its remit – which no longer included astronomy; biotechnology and biological sciences; space research and particle physics. In fact, from its inception, EPSRC was a very different beast from SERC
(1981-1994) and its predecessor, the
Science Research Council (1965-81).
In addition to a more focused remit, from
Day One EPSRC set about streamlining its core activities, and its staff adopted a more focused approach to everything they did.
An example is the early transition to solely electronic research grant applications.
With an average of 5,000 submissions per year, at a stroke efficiency was dramatically improved, costs came down and staff had more time to support and engage with the research community.
Interviewed in1994, Chairman, Dr Alan
Rudge (pictured), explained EPSRC’s founding priorities:
“EPSRC has an exciting and challenging mission to support high-quality research in the UK, and to make significant contributions to national competitiveness and to the quality of life.
“There are three main objectives:
• Developing and sustaining a national core competence in engineering and the physical sciences
• Maintaining a world-class teaching capability in terms of both technical content and techniques
• Advancing scientific knowledge
EPSRC 1994-2014 March 29: Serbs and Croats sign a cease-fire to end the war in Croatia
“Our task is to judge the work we support not only on the excellence of its research, but also on its relevance to the requirements of users in industry, commerce and elsewhere.
“The most important form of technology transfer from the science base is the flow of people out of the universities into industry, commerce and government.
“If we only supported long-term curiositydriven research, we would have a badly balanced portfolio. On the other hand, if we only supported short-term research, driven by immediate and obvious relevance, there would be something seriously amiss.
“The object is to maintain a well-balanced portfolio – and this is what EPSRC will seek to achieve.”
Over two decades, EPSRC has stayed true to these principles, which are enshrined in its Royal Charter of 1994.
4

In the summer of 1994, capping a decade of intense research, a team of British chemists from the University of Birmingham and Imperial College London worked out the exact structure of a billionth-scale molecular version of the Olympic emblem, called olympiadane, consisting of five tiny interlocking rings of atoms.
Olympiadane is a chain of rings and was something of a record in the field of supramolecular chemistry.
To get the rings together, the
Birmingham team, led by Dr Fraser Stoddart, used supramolecular chemistry – where simple pieces are joined to make more complex supermolecules.
The techniques devised to create the molecule may shed light on the process by which life arose from relatively simple chemicals.
Research such as this could also lead to new smart polymers that respond to their environment, and superfast, nanoscale devices for the computers of the future.
In 1994, in a move that set the blueprint for EPSRC’s commitment to wider engagement with the academic, business and stakeholder communities, EPSRC set up two independent advisory panels to advise the chief executive on future research areas and their value.
The Technical Opportunities Panel
(TOP), which mainly comprised academics, and the User Panel
(UP), whose main component was industrialists, advised on how
EPSRC’s budget could be divided in order to get maximum benefit, and also suggested priorities for many of
EPSRC’s research programme areas.
The new panel system was so successful it remained largely unchanged for nearly two decades, and was complemented in 2007 by a Societal Issues Panel (SIP) before evolving into a Strategic
Advisory Network in 2011, which offered a more flexible advisory model combining multiple stakeholder perspectives.
In 1994, EPSRC was allocated
£364 million by the government for its first year in existence. It went on to invest £212 million in academic research grants; £72 million in the training of postgraduate students and
£52 million in support of the Daresbury and Rutherford Appleton Laboratories.
The responsibility for these facilities was later passed on to the Science &
Technology Facilities Council (STFC).
In 2014, EPSRC is responsible for an annual research and training budget of around £800 million. Around 25 per cent of this is allocated to doctoral level training.
In April 1994, EPSRC launched its Innovative Manufacturing
(IM) programme, which aimed to bring industry and academia together for the benefit of British manufacturing industry.
Joint sponsors of the programme included the Economic and
In 1994, Professor
Lynn Gladden, from the University of
Cambridge, was awarded £360,000 by
EPSRC to establish a centre of expertise in the application of nuclear magnetic resonance (NMR) spectroscopy for use by the UK academic process engineering community.
NMR spectroscopy is a quality control technique used in analytical chemistry to determine a sample’s content, purity and molecular structure.
The grant consolidated Professor Gladden’s reputation as a pioneer in the development of NMR techniques, including translating them from the laboratory into industrial practice. She has since received over
30 research grants from EPSRC.
In 2001, Professor Gladden (pictured) was awarded the OBE for her services to chemistry and elected a Fellow of the Royal
Society in 2004.
In 2006, she was appointed to EPSRC’s
Council, its senior decision-making body.
In 2009, she was awarded the CBE for her services to science.
In 2013, Professor Gladden was named as a co-leader of the new UK Catalysis Hub, a
£12.9 million EPSRC investment in catalytic science. The Hub is an academic/industrial collaboration focused on supporting UK economic growth while helping reduce
CO
2
emissions, produce cleaner water and generate more sustainable energy.
Today, Professor Gladden leads the
University of Cambridge’s Magnetic
Resonance Research Centre and is also the university’s Pro-Vice-Chancellor for Research.
Social Research Council (ESRC), the
Biotechnology and Biological Sciences
Research Council (BBSRC) and the
Department of the Environment.
The programme marked an important step up towards a ‘joined-up’ approach to fostering multidisciplinary partnerships between the science base and industry that continues to this day.
EPSRC 1994-2014 April 6: The Rwandan Genocide begins. In 100 days some 800,000 Tutsis and moderate Hutus were massacred
5

1994
In the mid-
1990s, work by VSLI Vision
Limited (VVL), a small Scottish electronics company formed to commercialise the work of
Professor Peter
Denyer and
Professor David Renshaw at Edinburgh
University, led to the development of electronic chips that can ‘see’ – paving the way for a revolution in mobile cellular technology – the camera phone.
Previously funded by EPSRC’s predecessor, the Science and Engineering Research
Council (SERC), and then by EPSRC in
1994, Professor Denyer (pictured) and his team pioneered the development and manufacture of CMOS (complementary metal-oxide semiconductor) sensor technology now used in almost all mobile phones and also employed in digital cameras, webcams, video-conferencing cameras and the optical computer mouse.
Conventional video cameras of the day had separate light sensors that took images and created electronic signals, which then went on to another piece of electronic hardware.
VSLI’s breakthrough combined image capture and processing on a single chip, and set the stage for Professor Denyer and his team to step into history.
VSLI evolved into Vision Group plc and became an early manufacturer of CMOS image sensors, at its peak selling one million cameras a year.
By 2006 , half of all mobile phones had digital cameras. It is estimated that in 2014 the number of mobile phones globally will exceed the number of people on the planet.
Professor Denyer went on to become a prolific entrepreneur, adviser and mentor to university start-up companies and a serial investor.
In 1998, Peter Denyer was awarded the
Royal Academy of Engineering’s
Silver Medal, and, in the same year, together with colleagues
David Renshaw, Lu Mingying, and Wang Guoyo, he was awarded the Rank Prize in
Optoelectronics for their pioneering research.
Accepting the Rank Prize,
Professor Denyer said: “Our work was not always so well regarded, certainly in its earliest days when the doubters were many and the believers were... well, just ourselves.”
The Royal Society has described Professor Denyer, who died in 2010, as ‘a unique combination of electronics engineer, distinguished academic, inventor, company
CEO and multiple entrepreneur’.
“To say that Denyer ‘invented’ the mobile phone camera,” wrote one obituarist, “would be unfair to the rest of his research team at Edinburgh University and to parallel researchers worldwide...
“But, although the camera phone phenomenon was but a twinkle in Denyer’s eye when he started out, he became internationally-recognised as a driving force in the technology known as CMOS which still features in hundreds of millions of mobile phones around the globe.”
In 2012, Facebook paid a billion dollars for
Instagram, a small business that develops novelty software to make your phone pictures look like old Polaroids.
EPSRC 1994-2014 April 18: Cricketer Brian Lara hits a world record 375 runs in one day
6

EPSRC 1994-2014 May 10: Nelson Mandela is sworn in as South Africa’s first black president
7

1994
In 1994, EPSRC awarded a grant of £390,000 to an engineering research team at Imperial College London to examine subsidence caused by extension tunnelling.
The team was led by soil mechanics expert Professor John
Burland, who went on to play a leading role as a member of an international team commissioned by the Italian
Government to stabilise the Leaning Tower of Pisa – a feat they achieved in 2001.
The team, which was also funded by the Department of the Environment and London Underground, conducted important work that informed the safe construction of
London’s new Jubilee extension line.
Interviewed in 1994, Professor Burland said:
“Research in subsidence has been almost impossible, because it has always happened by the time you get on the scene. The Jubilee extension gives us an ideal opportunity to observe how buildings respond to subsidence.”
In addition to the Pisa project,
Professor Burland advised on a project to ensure the stability of the Big Ben Clock Tower.
In May 2008, engineers announced that the Leaning
Tower of Pisa had been stabilised and that they had stopped the building from moving for the first time in its history. In April 2011, the scaffolding was removed.
Today, Professor Burland is working with London
Underground and Crossrail on an EPSRC-sponsored project to assess potential damage to existing tunnels before and after excavation works as part of the multi-million pound
London Crossrail project.
8
EPSRC 1994-2014 May 6: The Channel Tunnel linking England and France officially opens

In 1994, marine energy pioneer Artemis
Intelligent Power was formed to commercialise EPSRC-supported research into hydraulic wave energy technology developed by Professor Stephen Salter
(pictured) and Dr Win Rampen at the
University of Edinburgh in the 1970s and 80s.
Artemis Intelligent Power performs research, development, and technology licensing associated with Salter and
Rampen’s Digital Displacement® (DD) technology, as well as other innovations in the control and transmission of fluid power.
Artemis has won numerous industry awards for its energy-saving applications, and continues to work with global companies to develop DD systems and power transmissions for a range of energy-saving applications, including highway and off-road vehicles. A specially adapted BMW saloon has achieved fuel savings of 30 per cent.
In 2010, Artemis Intelligent Power was acquired by Mitsubishi Power Systems
Europe (MPSE); it is currently developing a unique gearless power transmission for very large offshore wind turbines.
In 2014, Artemis’ parent company, Mitsubishi
Heavy Industries Ltd (MHI), established a new joint venture company with Vestas Wind
Systems dedicated to business in offshore wind turbines.
Plans for the new company include an early market launch of a turbine incorporating the world’s first Digital Displacement®
Transmission.
Artemis has also designed and manufactured valves, electronics and control software for two new wind turbines for
Mitsubishi for deployment in the west of
Scotland and offshore of Fukushima, Japan.
Today, Professor Stephen Salter, who received the Sustained Achievement Award from the Royal Academy of Engineering in 2012, remains a director of Artemis
Intelligent Power. The device he designed in the 1970s, the Salter Duck, was one of the world’s first wave energy devices and remains one of the most efficient.
Professor Salter is Emeritus Professor at the UK Centre for Marine Energy Research at Edinburgh University, supported by the
SUPERGEN Marine Energy Consortium, led by EPSRC (see page 48).
9
EPSRC 1994-2014 August 31: The Provisional Irish Republican Army announces a “complete cessation of military operations”

1995
In 1995, Lionel
Tarassenko
(pictured in 1995), an EPSRC-funded researcher from the University of Oxford’s
Department of
Engineering
Science, developed the core technology behind the Sharp Logicook, the world’s first ‘smart’ microwave oven. It is an early highlight in a remarkable career
– particularly in the field of biomedical engineering.
Professor Tarassenko’s pioneering work, originally in neural networks and subsequently in machine learning, led to a host of different applications based on pattern recognition – from jet engine diagnostics to patient monitoring.
Professor Tarassenko’s research has brought him international recognition for his work in signal processing and biomedical engineering, and he has held the Chair in Electrical Engineering at the
University of Oxford since 1997.
In 2000, he was awarded a Fellowship from the Royal Academy of Engineering. Six years later he was awarded the Academy’s
Silver Medal for his contribution to British engineering. Today, he chairs the Royal
Academy of Engineering’s Biomedical
Engineering Panel.
In 2008, Professor Tarassenko was awarded the Rolls-Royce Chairman’s
Award for Technical Innovation for his work on jet engines. This award followed the
Sir Henry Royce High Value Patent Award seven years earlier, in 2001.
Also in 2008, Professor Tarassenko became the first Director of the Oxford Institute of
Biomedical Engineering (IBME). The IBME hosts a Centre for Doctoral Training in
Healthcare Innovation, under the EPSRCled RCUK Digital Economy programme.
It also hosts a Centre of Excellence in
Medical Engineering funded jointly by the
Wellcome Trust and EPSRC and led by
Professor Tarassenko.
Commercial success
A successful entrepreneur, Professor
Tarassenko has founded several spin out companies, including t+ Medical, Oxford
BioSignals Ltd and Oxehealth. Awardwinning products include t+Diabetes, a mobile phone-based tool for diabetes selfmanagement; and a system for gestational diabetes management, which have been taken up by hospitals throughout the Oxford region, from Reading to Milton Keynes.
In 2006, Professor Tarassenko won the
Institute of Engineering & Technology
IT Award for Visensia, a data fusion system providing early warning of patient deterioration in critical care. It was the first data fusion system to be approved by the
US Food and Drug Administration. Over
137 licences for the product have been sold in the UK and the US in the last two years.
In 2013, Professor Tarassenko launched a new iPad-based early warning patient monitoring system for ward-based monitoring in hospital. The system, developed under the EPSRC-led RCUK
Digital Economy Programme, uses the latest computer tablet technology to record and evaluate patients’ vital signs. The system is being rolled-out across all adult wards in the Oxford University Hospitals
NHS Trust’s acute hospitals, with funding from the NHS Technology Fund and the
Safer Hospitals, Safer Wards programme.
Origins
Lionel Tarassenko’s career-long passion for digital signal processing began in the early 1980s at Racal, before it evolved into
Vodafone, which he joined as a graduate, at a time when mobile telephony was still just an idea. His time at Racal included work on the company’s first speech coder, which enabled the spoken word to be captured and transmitted digitally.
After three years at Racal, Professor
Tarassenko returned to academia to study for a doctorate in biomedical electronics in paediatrics. He has remained in academia ever since, and recently returned to paediatrics-related research to work on the non-contact monitoring of babies’ vital signs using webcams. He describes his move back into university-based research as the best decision he ever made.
Professor Tarassenko says: “I have been very fortunate that my research has made a positive difference to the care of tens of thousands of patients, and has been translated into products which have monitored the efficiency of thousands of jet engines.”
10
EPSRC 1994-2014 January 12: A major earthquake kills 5,092 people in Kobe, Japan

EPSRC 1994-2014 26 February: Barings Bank, the UK’s oldest merchant bank, collapses following £840 million of losses incurred by rogue trader, Nick Leeson
11

1995
In 1995, an EPSRC-supported team led by
Professor Peter Bruce, from St Andrews
University, developed a rechargeable
Lithium battery material enabling lighter, more reliable, more efficient and greener batteries than the prevailing Nickel
Cadmium (NiCad) type.
Over the next two decades, Professor
Bruce (pictured) attracted substantial and continuous funding from EPSRC, The Royal
Society and internationally. He and his colleagues made important advances in the science underpinning rechargeable Lithium batteries, particularly enhancing their ability to store and retain charge.
He is part of a team of four innovative scientists behind research into developing
Lithium-ion batteries for electric vehicles.
Together, Professors John Goodenough,
Mike Thackeray, Bill David and Peter
Bruce were able to discover electrode materials resulting in a lower cost and safer alternative to the more expensive
Lithium cobalt oxide electrodes, which are unsafe when used in large batteries. As a result, the Lithium manganese oxide spinel became the material of choice for the first generation of modern electric vehicle batteries, used in cars such as the Nissan
Leaf and Vauxhall Ampera.
In 2007, Professor Bruce was elected a Fellow of the Royal Society. He is one of the pioneers of the Li-air (O
2
) battery, which can exceed the energy density of rechargeable Lithium-ion (Li-ion) batteries and could hold the key for next-generation energy storage devices, including for electric vehicles.
In 2012, Professor Bruce received the
AkzoNobel Science Award from the Royal
Society of Chemistry in recognition of his outstanding scientific contribution in the fields of chemistry and materials science.
In 2014, Professor Bruce FRS, now at the
University of Oxford, is working on three
EPSRC-funded projects on the materials chemistry and electrochemistry of Lithiumair, Lithium-ion and sodium-ion batteries.
The project is funded under the Sustainable
Power Generation and Supply (SUPERGEN) initiative, part of the RCUK Energy
Programme, led by EPSRC.
Professor Bruce says: “Lithium batteries are one of the most important technological developments of the past 20 years. The UK has played a central role in this technology.
New materials and new electrochemistry will continue to drive the field, leading to new generations of Lithium batteries for use in transport and electricity grid storage.”
In May 2014, EPSRC invested £4 million in a new SUPERGEN Energy Storage Hub, led by
Professor Bruce (see page 48).
EPSRC 1994-2014 April 19: A truck bomb at Federal Building in Oklahoma City kills 168 and injures 500
12

In 1995, EPSRCsupported research into renewable energy, co-led by Dr Paul
Adcock and Dr
Phil Mitchell, from
Loughborough
University, resulted in a hybrid battery/fuel cell power source for road vehicles. The fuel cell was used at cruising speeds while a set of batteries provided acceleration.
The objective was to create an entirely new sustainable power source that would slot into the same space as existing engines.
Interviewed in 1995, Dr Adcock (pictured in 1995) said: “The great thing is that from the driver’s perspective the experience will be just the same as a conventional vehicle.”
His optimism was well-founded.
In June 1995, together with Dr Jon Moore and Anthony Newbold, Adcock and Mitchell formed university spin out company
Advanced Power Sources (APS) Ltd to commercialise their work.
In 2001, their work led to the formation of another spin out company, Intelligent
Energy, which absorbed APS as part of its strategy. A core team of EPSRCfunded researchers from Loughborough
University joined the company at its inception and to this day continues to lead its R&D, providing stability and insight into product development.
Today, Intelligent Energy is one of the fastest-growing companies in Europe and is the world’s largest independent fuel cell company.
With 350 staff across operating sites and offices globally; it has established major global partnerships including with the
Suzuki Motor Corporation with whom it has formed a joint venture company in Japan.
The company retains close links with
Loughborough and other major UK universities, and over half its employees hold PhDs. In the last decade it has achieved a host of notable achievements.
In 2005, the company unveiled the world’s first purpose-built fuel cell motorbike
(pictured), which emits only water vapour, is near-silent and non-polluting.
In 2008, the company’s fuel cell technology was used in the first manned flight of a fuel cell-powered aircraft by Boeing.
In 2012, a fleet of zero carbon London taxis was used to transport passengers at the London Olympics. The taxi’s hydrogen fuel cell system, hydridised with Lithium polymer batteries, allows the vehicles to operate for a full day without refuelling, and gives them a top speed of 80 mph.
In January 2014, in partnership with US retailer and product development company,
Brookstone, Intelligent Energy launched the Upp™ personal energy device to power USB compatible portable electronic devices. The device provides at least one week of charge even to the most powerhungry smartphones.
In March 2014, Intelligent Energy received
£38 million from GIC, the Singapore
Government’s sovereign wealth fund, for
10 per cent of its share capital, to build its consumer electronics and distributed power and generation divisions.
In 1995, EPSRC started its new system for the peer review of grant applications by independent experts. The new peer review college comprised 1,650 individuals from academia and industry grouped into
16 colleges of varying size based on
EPSRC research programmes.
Every research proposal was assessed by at least two college members together with one person from a list put forward by the proposer.
After an initial sift based on referees’ reports, small panels drawn from college members put the remaining proposals into peer-ranked order, which went towards the decision about which proposals should be funded.
For 20 years the peer review system has evolved and matured, but retains true to its founding values.
Over a decade before the advent of chip and pin technology and smartphone banking, the cashless society took a step closer in
1995 with the trial launch of Mondex, an electronic purse introduced by NatWest
Bank, Midland Bank and BT.
The Mondex smart card, which resembled a pocket calculator, was launched in
Swindon, where residents had the chance to experience e-purchasing for themselves.
Mondex allowed users to transfer cash from bank accounts to the card and back again using card-readers.
Behind Mondex was a research team led by
Professor Haroon Ahmed at the University of Cambridge’s Microelectronics Centre, who spent three decades of EPSRC/SERCfunded research on the reverse engineering of silicon chips and the inspection of integrated circuits, which they used to test
Mondex’s integrity. The team also made important inroads into the integration of sensors and electronics on the same chip.
Mondex didn’t catch on, but Professor
Ahmed’s research demonstrated the possibility of safe and secure e-banking.
EPSRC 1994-2014 British mountain climber Alison Hargreaves becomes the first woman to climb Mount Everest without oxygen or assistance.
13

1996
In 1996, the first DVD players went on sale.
But what if they never existed?
Imagine a world without the internet, DVDs or barcodes. If it weren’t for one man, Professor
Alf Adams (pictured), from the University of Surrey, the technology that made these inventions so widely available, or indeed possible, might never have been invented.
Supported by funding from EPSRC’s predecessor, the Science and Engineering
Research Council (SERC), Professor
Adams’ ground-breaking research into infrared lasers at the University of Surrey in the 1980s paved the way for a host of low-cost and low-power commercial and industrial products without which the modern world could not function.
Research underpinned by this technology continues to this day. The internet in particular, which relies on Alf Adams’ strained layer laser technology, has made it possible to send information around the planet much more quickly than was hitherto possible.
The internet is physically connected by hugely complex fibre-optic technology underneath the world’s oceans, which it uses to send light from one continent to another.
The data carried by these fibre-optic networks is not stored in ‘clouds’ as we might think, but in huge data centres in strategic sites across the globe, the largest of which require the power it takes to light a small city to keep their hard drives spinning and, crucially, keep them cool.
According to a 2010 Greenpeace report, two per cent of the world’s electricity usage can now be traced to these data centres.
It’s estimated that the internet accounts for around three per cent of the world’s total energy consumption, a figure that is growing exponentially.
In 2014, a team at the University of Surrey led by Professor Stephen Sweeney, a former PhD student under Alf Adams, are carrying forward Alf’s legacy, and are applying new advances in infrared laser technology to tackle emerging challenges such as the internet’s insatiable need for power.
Professor Sweeney, who holds an EPSRC
Leadership Fellowship, and who leads the Surrey Photonics Group, says: “A key element of my Fellowship is to re-engineer the basic crystalline materials from which the lasers are made.
“If our research proves to be correct, then most of the temperature control electronics required by internet lasers could be removed – leading to a substantial reduction in their energy demand.”
In 2014, Alf Adams, now Emeritus
Professor at Surrey, was awarded the prestigious Rank Prize in optoelectronics for his research into the structure of semiconductor lasers.
Although he did not file a patent for his invention, and so has not made a penny from it, he has no regrets.
EPSRC 1994-2014 October 3: OJ Simpson is found not guilty in the murder of Nicole Simpson and Ron Goldman
14

EPSRC 1994-2014 November 22: Toy Story is released. It is the first feature-length film created entirely using computer-generated imagery
15

1996
In 1996, University of Cambridge metallurgist Professor Harry Bhadeshia developed a new, carbide-rich and siliconfree steel alloy for railway tracks, which promised to be tougher and more resistant to fatigue than traditional materials.
The alloy had remarkable properties: as well as being enormously resistant to wear itself, it also reduced wear on the train wheels, which was almost unheard of.
Professor Bhadeshia received support for his basic research into steel from EPSRC.
Every year, 17 million people pass along rails made from Harry Bhadeshia’s steel, which form the backbone of the 31-mile Channel
Tunnel rail link, Europe’s busiest railway.
In 2009, the SKF University Technology
Centre on Steels was set up in Cambridge, with Professor Bhadeshia as its head. The
Centre continues to pioneer research in advanced bearing technology for aircraft engines, with major support from industry, supplemented by EPSRC.
In 2011, the UK Ministry of Defence unveiled a new type of vehicle armour, using another of Professor Bhadeshia’s inventions. The armour is made from super bainite, the strongest low-alloy steel that has ever been produced, more than six times stronger than conventional steel.
It is also the world’s first nanostructured material to be manufactured in bulk.
Now, with sponsorship from the Ministry of
Defence, and with EPSRC input, Professor
Bhadeshia is attempting to design a kind of steel that has what he calls an “impossible combination of properties”.
The new steel will be strong enough to be ballistic and blast-resistant, but also capable of being welded, meaning it will be possible to make large things out of it, such as military vehicles.
Over the last 20 years, Harry Bhadeshia has seen significant changes in his field.
He says: “The intensity of research has increased enormously; with industry realising that a good way of carrying out long-term work is to put it out to universities. But academics benefit too – industry gives us an awareness of critical issues which we couldn’t get just from reading academic papers.”
Computer modelling has also come on enormously, and is integral to Professor
Bhadeshia’s research. He says: “I think of computer modelling as being like electron microscopes, which we also use a lot of. It helps to cut out the variables, and identify where new knowledge is needed.”
Since 1990, the Material Algorithms Project
(MAP), funded by SERC/EPSRC and led by
Professor Bhadeshia, has been particularly important in this field, freely distributing algorithms useful in generating computer models of materials.
Professor Bhadeshia says: “MAP is now the largest free source of these algorithms in the world. Without EPSRC’s support, it would not have been possible.”
March 16: Mike Tyson knocks out Frank Bruno in the third round to win the world heavyweight boxing title
16
EPSRC 1994-2014

In 1996, Professor Wendy
Hall, from the University of Southampton, was awarded a fiveyear EPSRC Senior
Fellowship to develop the multimedia assistants of the future.
One of the first computer scientists to undertake serious research in multimedia and hypermedia, Professor Hall has been at the forefront of this multifaceted discipline ever since.
The influence of her work has been significant in many areas including digital libraries, the development of the Semantic
Web, and the emerging research discipline of Web Science – the science of the World
Wide Web.
In 2006, Professor Hall was a founding director, with Professor Sir Tim Berners-
Lee, Professor Sir Nigel Shadbolt (see page 119) and Daniel J Weitzner, of the Web
Science Research Initiative, a global forum for scientists and scholars to collaborate on the first multidisciplinary scientific research effort specifically designed to study the Web at all scales of size and complexity.
In 2008, Professor Hall was elected
President of the Association for Computing
Machinery (ACM), the world’s leading community of computer scientists.
In 2007, among over 20 EPSRC research grants she has received, Professor Hall established with Professors Leslie Carr and
Nigel Shadbolt a Web Science Network for researchers from different technical and social science research disciplines to develop a research agenda. Among the network’s activities are exchange schemes for doctoral students and collaborative workshops.
In 2009, Professor Hall became a Dame
Commander of the British Empire. In the same year she was elected a Fellow of the
Royal Society.
Also in 2009, Professor Dame Wendy Hall became principal investigator of the new
EPSRC Centre for Doctoral Training in
Web Science, based at the University of
Southampton and led by Professor Leslie
Carr. The centre has evolved into the EPSRC
Centre for Doctoral Training in Web Science
Innovation, which Dame Wendy has led from its inauguration in October 2014.
Throughout her career, in addition to playing a prominent role in the development of her subject, Professor Hall has helped shape science and engineering policy and education and has also championed the role of women in science, engineering and technology.
In 1996, a collaboration between a
University of Portsmouth research team and manufacturer Cetrek led to the development of a ‘smarter’ autopilot for motor boats, trawlers and small ships.
The device used a ‘fuzzy logic’ controller, designed by Dr Martyn Polkinghorne from the University’s School of Manufacturing,
Materials and Mechanical Engineering, to learn about its own performance and make allowances for heavy cargo, the weather and changing tides.
The device used self-organising techniques to ensure the vessel arrived at its pre-set destination efficiently.
During sea trials the system was 50 per cent faster than a standard autopilot when taking a 90 degree turn.
Dr Polkinghorne and his new autopilot were subsequently featured on BBC science programme Tomorrow’s World.
In 1996, Professor Mike Griffin, from the
University of Southampton’s Institute of
Sound and Vibration Research, developed procedures for predicting seasickness.
These were subsequently incorporated into international standards used by ship designers and shipping operators.
Professor Griffin’s team’s earlier study of ships, coaches and small passenger aircraft identified which motions in each
EPSRC 1994-2014 form of transport cause sickness.
In seasickness, for example, the up and down motion is to blame; in road vehicles the horizontal motions – braking, accelerating and cornering – tend to cause discomfort.
A second tranche of EPSRC funding enabled Professor Griffin and his colleagues to research the design of vehicle seating arrangements and also the prediction of motion sickness.
In 1999, after surveying over 3,000 coach passengers, the team concluded that people are more likely to feel sick during road travel when a vehicle is cornering or making a similar manoeuvre.
However, when passengers are provided with a good view of the road ahead feelings of motion sickness are reduced – suggesting that travel sickness could be significantly reduced by improved forward external vision.
In 1996, two members of a team that triumphed in the final of BBC Television’s
University Challenge, Nick Bradshaw and
Jim Totty, were PhD students supported by EPSRC.
The key to their success was simple, according to Nick Bradshaw, and was all down to the nature of the scientific mind.
Interviewed in 1996, he said: “I think there are more science students who can answer arts questions than there are arts students who can answer science questions.”
Today, Nick Bradshaw (below middle left) is Vice President of Equity Derivative
Development at Barclays Capital.
December 10: The General Motors EV1, the first production electric car of the modern era, is launched and becomes available for lease
17

1996
In 1996, Professor Brian Wilshire from the
University of Wales, Swansea, developed
‘magnetic flake’ powders that would allow scene-of-crime officers to study fingerprints without having to brush them with fine powder, which could lead to smudging.
The powder consisted of tiny iron flakes with an organic coating that helped it stick to the greasy residue in a fingerprint. A key element of the process was the use of magnetism to remove excess powder, preserving the delicate ridge lines that make each print unique.
The technology was successfully trialled by the UK Forensic Science Service and led to the launch of a spin out company to commercialise Professor Wilshire’s research, K9 Scene of Crime Equipment
Ltd, (later Crime Scene Investigation
Equipment Ltd).
Today, staffed by ex-members of the police and security services, the company has developed a wide product portfolio, ranging from inking systems and casting materials to fire and explosive detection systems.
The company’s Magneta Flake™, manufactured specifically for the recovery of latent fingerprints, is fast becoming the first choice preference with many law enforcement agencies.
A ‘dark’ form of the flake, for use on lighter surfaces, has been developed in conjunction with the University of
Central Lancashire with additional funding from EPSRC.
18
EPSRC 1994-2014 June 23: The Nintendo 64 goes on sale in Japan

In 1996, EPSRC began successful trials that resulted in the introduction of full electronic submission of research proposal forms.
With an average of 5,000 grant applications from researchers received each year since 1994, the initiative dramatically improved efficiency, drove down costs, and enabled EPSRC staff to spend more time on supporting the research community and devote less time on paper-led administration.
In 1996, Professor Cliff Burrows, Director of the Fluid Power Centre at the University of Bath, was awarded £445,000 by EPSRC to study driveline controls in cars; focusing on maximising efficiency and reducing emissions.
The research built on a project funded by the Department for Trade and Industry,
Ford, Lucas and Johnson Matthey.
A key element of the project was a constantly variable transmission, which effectively made gear changing stepless, so the engine could work at peak efficiency across a wide range of operating conditions, improving fuel economy.
In 2001, Professor Burrows was made
Director of the newly established EPSRC
Innovative Manufacturing Research Centre at the University of Bath (see page 36). In
2001, Professor Burrows received the OBE.
In 1996, a team led by Dr Dougal Drysdale at the University of Edinburgh’s Fire Safety
Research Group used an EPSRC-funded research grant to develop mathematical models to predict the way fires develop in buildings and in tunnels.
The team also used EPSRC funding to build test apparatus to measure the upward spread of flames on walls.
Dr Drysdale went on to write the seminal reference text on fire protection engineering, An Introduction to Fire
Dynamics, in 1999.
Today, Dr Drysdale is acknowledged as a leading international authority in his field.
He said it
In the long term there will be all-electric cars which will have a tiny internal combustion engine driving a generator to provide power to electric motors in the wheels.
Interviewed in 1996, this prediction was made by
David Davies, Director of the Human Sciences and Advanced Technology Research Institute at the EPSRC-supported Loughborough University of Technology,
In 2012, nearly two decades after making this statement, David Davies is bang on the money, when UK car manufacturer, Lotus, unveiled its
Evora 414E hybrid vehicle. The fully working concept vehicle was developed in collaboration with a consortium of
EPSRC-supported engineers.
The Evora (pictured) uses a hybrid electric drivetrain. Electrical energy is provided to the battery by a compact, lightweight, low-cost, 1.2 litre petrol engine and generator. Each drive wheel is connected to an electric motor which allows for independent rear-wheel control.
The Evora’s battery can be charged overnight using a conventional domestic mains supply. Further innovations include regenerative braking control and adaptable suspension designed to both increase fuel economy and enhance the driving experience.
The work is part of the FUTURE vehicles consortium comprising seven universities and 10 industry advisers and is funded under the £10 million
Low Carbon Vehicle Integrated Delivery
Programme, funded by EPSRC and the
Technology Strategy Board.
The team estimate that cars featuring this technology will be on sale by the end of this decade.
EPSRC 1994-2014 July 4: Hotmail, a free internet e-mail service, is launched
19

1997
Words: Phil Davies
EPSRC 1994-2014 February 23: Scientists in Scotland succeed in cloning an adult mammal, dubbed Dolly the Sheep
20

Behind this feat was a team led by World
Land Speed Record-holder Richard Noble, with RAF jet fighter pilot, Andy Green, behind the wheel.
Playing a crucial part in Thrust’s supersonic success were Professors Nigel
Weatherill, Ken Morgan and Dr Oubay
Hassan, a team of EPSRC-supported researchers from the University of
Wales, Swansea.
The team, having previously worked with the likes of NASA, Rolls-Royce and British
Aerospace, were approached by Richard
Noble who asked them to use their computational modelling techniques to help design Thrust SSC.
Through the use of two Cray Research supercomputers, one at Edinburgh
University, supported by EPSRC (see
EPSRC 1994-2014 page 86), and the other at the Rutherford
Appleton Laboratory, the Swansea team used their aviation design software to refine the concept of rear-wheel steering. This involved the use of computational fluid dynamics (CFD) – numerical methods and algorithms to analyse the flow of fluids.
Following computer simulations of the run, the team discovered a potential issue: the shockwaves generated when breaking the sound barrier.
Not only would the shockwaves ricocheting off the ground and back at Thrust make the supersonic vehicle slow down, they could prove disastrous, causing it to flip and crash.
After two years of testing and exhaustive computer modelling, the Swansea researchers succeeded in helping
May 2: Labour wins the UK General Election the Thrust SSC design team develop and construct a viable design for the
16.5 metre, 10.5 tonne car.
There was still a world record to beat.
Team Thrust then travelled to Black Rock
Desert in Nevada, where they successfully smashed the 1983 World Land Speed
Record held by Richard Noble himself with the 663 mph Thrust 2, and zoomed into the record books.
In 2008, EPSRC became a founding sponsor of the BLOODHOUND SSC project,
Richard Noble’s latest land speed record attempt. The plan is hugely ambitious
– to design and build a car capable of exceeding 1,000 mph (see page 85).
Professors Hassan and Morgan are providing their expertise in computational fluid dynamics to the project.
21

1997
In 1997, an EPSRC-supported team from the University of Bath, led by Professor
Malcolm Greaves, collaborated with
Petroleum Recovery Institute, Calgary,
Canada, on an innovative project to release ‘heavy’ oil and bitumen trapped in underground reservoirs. These crude oils are very difficult to recover because of their high viscosity.
Over the next decade-and-a-half,
Professor Greaves, who began research into the technology in 1990, continued to refine the revolutionary Toe-to-Heel Air
Injection (THAI™) system.
The THAI process injects air into the oil deposit down a vertical well and then ignites it. The heat generated in the reservoir reduces the viscosity of the heavy oil, allowing it to drain into a second, horizontal well from where it rises to the surface. With EPSRC’s support, the research led to an ‘add-on’ catalytic process, known as CAPRI.
In 2006, Petrobank Energy and Resources,
Calgary, started the first THAI field pilot at
Conklin in the Athabasca Oil Sands region of Alberta, Canada, the largest single petroleum resource on the planet.
Interviewed in 2007, Professor Greaves said: “It’s been a struggle to get the invention from an idea to a prototype and into use. For most of the time people weren’t very interested because heavy oil was so much more difficult and expensive to produce than conventional light oil.
“But with light oil now hitting around
$100 a barrel, it’s economic to think of using heavy oil, especially since THAI can produce oil for less than $10 a barrel.
“We’ve seen this project go from something that many people said would not work into something we can have confidence in, all in the space of the last 18 months.”
Today, THAI is undergoing commercial development at Kerrobert in Saskatchewan,
Canada. Meanwhile, a team led by
Professor Joe Wood, from the University of
Birmingham, including colleagues at the universities of Nottingham and Manchester, are using high pressure experiments and specialised computer modelling software to simulate the detailed behaviour of the
THAI-CAPRI process for in-situ catalytic upgrading of heavy crude and bitumen.
In addition to heavy oil reservoir research, the team are investigating light oil applications, where air can be used as an injectant gas for medium and high pressure reservoirs. Emeritus Professor Malcolm
Greaves, who is an adviser on the project, says: ”In-situ upgrading of heavy crude, which is one of the main objectives of THAI/
CAPRI, is a massive advance for the oil industry. If it can be done effectively, it could save billions of dollars on refinery upgrades in the UK alone.”
At the University of Bath, Emeritus
Professor Greaves is conducting studies of downhole gasification in light oil reservoirs for improved oil recovery and hydrogen production/storage – generating a largescale source of hydrogen for the future hydrogen economy.
22
EPSRC 1994-2014 August 31: Diana, Princess of Wales, dies in a car crash in a road tunnel in Paris

With EPSRC funding, in 1997 Dr Jon
Binner, from the University of Nottingham, developed a way to dramatically speed up production of advanced ceramic components for use in high-tech applications such as military jet engines.
By reducing production time to hours rather than months, and hence reducing costs, the microwave treatment process opened up exciting possibilities for ceramic matrix component (CMC) processes in a much wider range of industries such as car manufacturing and mining.
The far-reaching project is one of over
20 EPSRC research grants related to ceramics and advanced materials awarded to Professor Binner, who in 2013 assumed the presidency of the Institute of Materials,
Minerals and Mining, a major engineering institution with 18,000 members.
Also in 2013, Professor Binner, now based at Loughborough University, received a five-year EPSRC grant to lead a project to develop materials for extreme environments, a collaborative programme between
Loughborough, Imperial College London and
Queen Mary, University of London.
In 1997, an EPSRC-supported research team at the University of Nottingham, led by Professor Saffa Riffat, developed a novel heat pump for heating and cooling buildings. Heat pumps collect heat from the environment instead of producing energy from burning fuel.
In the 2000s, Professor Riffat, now
President for the World Society of
Sustainable Energy Technologies, led an
EPSRC-sponsored team at the University
In 1997, Dr Jim Lesurf, from St Andrews
University, working with consumer and defence conglomerate General Electric
Company and the Defence Research
Agency, developed a low-cost system to help NATO forces avoid shooting their own side during a war.
Dr Lesurf’s project saw the development of a target identification device that would give allied vehicles the same radio signature as a warm rock or a tree. It built on his basic research in the fields of millimetrewave and terahertz technology, supported by EPSRC. Dr Lesurf led the mm-wave group at St Andrews before his retirement in 2004. of Nottingham, in partnership with
Roger Bullivant Ltd, to pioneer a process that turns the foundation piles of new buildings into heat exchangers for ground source heat pumps. The process has the potential to significantly reduce carbon dioxide emissions.
In 2010, the research project won the
Manufacturing & Process category at
The Engineer magazine’s Technology &
Innovation Awards.
In 1997, EPSRC introduced its pilot
Faraday Partnerships – a forerunner of the Technology Strategy Board’s
Knowledge Transfer Accounts. Aimed at improving the interaction between UK research and industry, the programme provided funding for academic research teams to forge partnerships with industry, particularly SMEs.
In total, 24 partnerships were funded under the initiative, which was run by the Department of Trade & Industry with funding from the UK Research Councils, with some partnerships evolving and flourishing to this day.
The Faraday Packaging Partnership, for example, brokers packaging technology and expertise for the academic and commercial spheres. The organisation sums up its winning formula with the following maxim: Nail the problem. Find the brains. Present the facts. Exploit the outcomes.
Another successful partnership,
3D-MATIC, which reconstructs 3D objects and scenes from photographic data, led to the foundation of the
Computer Vision & Graphics Group at the University of Glasgow, led throughout by Dr J Paul Siebert.
EPSRC 1994-2014 September 15: Two US students register a domain for a new kind of website. They call it Google
23

1998
In 1998, EPSRC awarded an
Advanced
Fellowship to
Professor Kevin
Shakesheff, from the University of
Nottingham, to continue his work in the emerging field of regenerative medicine – creating new advanced materials and technologies that help stem cells form human tissues.
Building on this research, Professor
Shakesheff (pictured) co-developed 3D scaffolds that can be injected into the body without the need for surgery, and which leave no solvents or toxic by-products.
The scaffolds are made from biodegradable polymers which, once inside the body, transform into an open-pored structure like a sponge, creating an environment for cells as well as for naturally occurring substances capable of stimulating cellular growth known as growth structures.
The work was stimulated by an EPSRC
Adventure Fund, which allowed the researchers to apply for funding at a much earlier, speculative stage.
Professor Shakesheff, together with
Professor Steve Howdle, also from the
University of Nottingham, found a way to process scaffolds outside of the body using carbon dioxide. Using this process enables scaffolds to form at low temperature and so preserves the growth factor and cells attached to them.
Continuous achievement
In 2000, Professor Shakesheff was named
Royal Institution Scientist for the New
Century; an award followed in 2001 by inclusion in the MIT Technology Review List of the World’s 100 Top Young Innovators.
In 2001, Professor Shakesheff formed spin out company Regentec Ltd to commercialise his research, developing a family of injectable scaffolds that solidify within the body.
In May 2014, Regentec rebranded as Locate
Therapeutics, after securing investment from precious metal and technology group
Heraeus Holding, which will help take the company to its next stage of development.
In 2002, Kevin Shakesheff and Steve
Howdle formed Critical Pharmaceuticals to bring their research to market. The company, which won the 2002 UK Research
Councils Business Plan Competition, is thriving to this day, and is developing unique biological drug products including controlled-release scaffolds.
In 2006, Professor Shakesheff became
Director of the Centre for Biomolecular
Sciences at Nottingham. Under his leadership, the centre has expanded into a multidisciplinary £25 million institute.
Much of the centre’s research falls within
EPSRC’s remit.
Since 2009, Professor Shakesheff has been co-Director of the EPSRC Centre for
Innovative Manufacturing in Regenerative
Medicine. He is also Director of the UK
Regenerative Medicine Platform Hub in Accellular Technologies, both at the
University of Nottingham.
In 2014, Kevin Shakesheff was named as one of the UK’s 10 most inspirational scientists and engineers in the EPSRC
RISE awards.
Transforming the treatment of disease
Among Professor Shakesheff’s commercial achievements, he has designed new materials which have since been licensed by three companies and which are being developed as products in Europe and the United States.
Professor Shakesheff says: “Regenerative medicine will transform the treatment of many of today’s ‘incurable’ diseases. But it’s going to take a long time and if we try to go too fast we will set the field back by many years. The reason for this is that regenerative medicines are very complex.
“My hope is that, within a decade, regenerative medicine will be able to create many products and treatments that have both commercial and clinical benefits.
“The final product will be a living entity that is probably personalised for just one patient.
“We know how to reprogram cells to become stem cells; we have technologies such as 3D printing and advanced materials that can build those cells into organ structures, and we understand a lot of the cell and tissue biology that allows tissues to form and repair.
“I can’t see any fundamental barrier that will stop future generations being able to grow a personalised organ. Specifically,
I hope to see, and help, stem cells being used to reverse the damage that occurs to the heart after a heart attack, restore patient health after a stroke and repair ageing joints.
“I would very much like these technologies to be the foundation of commercial and clinical success in the UK.”
24
EPSRC 1994-2014 May 23: The Good Friday Agreement is accepted in a referendum in Northern Ireland with 75 per cent voting yes

PIONEER 09 Winter 2013
25

1998
In 1998, for a few seconds, a corner of a lab in Brighton became the coldest place in the universe. Dr Malcolm Boshier and colleagues at the University of Sussex’s
Centre for Optical and Atomic Physics used lasers and magnets to trap and cool 100,000 rubidium atoms to just a few hundred-billionths of a degree above absolute zero (273 degrees Celsius).
Even the coldest parts of outer space are millions of times warmer than the temperature reached at Sussex.
When atoms are cooled to such low temperatures, strange things happen. The temperatures created what is known as a
Bose-Einstein condensate (BEC), the first time it had been achieved in Britain. It has been described as a new state of matter.
EPSRC 1994-2014
A BEC occurs when super-cooled atoms slow down, lose almost all of their energy, and are effectively frozen in space. The atoms then all behave identically to form what can be likened to a giant ‘superatom’ visible to the naked eye and big enough to photograph, yet which still follows the laws of quantum mechanics.
The BEC has become an important tool for investigating quantum behaviour, and could lead to new and exotic kinds of instruments such as fantastically sensitive microwave antennas, super-accurate
GPS navigation technology and quantum information processors.
Professor Ed Hinds, the centre’s director, and the project’s principal investigator, played a pivotal role in supporting
Professor Boshier’s activities, and then in taking the research forward.
In 1999, Professor Hinds was awarded an EPSRC Senior
Fellowship to further his research into cold atom physics. He has since
February 15: Comic Relief is born, beginning with the first Red Nose Day received over 20 EPSRC research grants, including a 2002 Basic Technology grant
(see page 30) to develop ‘atomic chips’.
This was followed by a Basic Technology
Translation grant.
Interviewed in 2005, Professor Hinds said: “By manipulating cold atoms, either individually or as a cloud or as a BEC, we hope to develop a completely new technology which will be as powerful as electronics or optics, but based on the flow of cold atoms instead of the flow of charged particles or photons.”
Among notable achievements since then, Professor Hinds pioneered on-chip integration of cold atom physics, most prominently demonstrated by creating a
Bose-Einstein condensate on a permanentmagnet chip.
In 2006, Ed Hinds became a Royal Society
Research Professor, under a scheme that allows senior researchers to devote their full time to research. The award, he says,
“made all the difference in letting me drive this technology forward”.
In 2008, he won both the Institute of
Physics Thomson medal and prize and the
Royal Society Rumford Medal.
In 2013, Professor Hinds FRS, now Director of the Centre for Cold Matter at Imperial
College London, received the Faraday
Medal from the Institute of Physics.
In 2013, the UK Government committed
£270 million over five years towards the development of quantum technologies.
Approximately £234 million was allocated to EPSRC.
Today, Malcolm Boshier is Scientific
Director of the Quantum Institute, Los
Alamos National Laboratory, USA, and part of a team attempting to harness atoms provided by a Bose-Einstein condensate to build new devices such as ultra-sensitive miniature sensors.
26

Meanwhile, in another part of the galaxy, in 1998 an
EPSRC-funded research team led by chemist David
E. Williams from University
College London designed an experiment that looked at the energy of chemical reactions where hydrogen and other atoms join together to form simple, small molecules.
The research helped to show that reactions which take place in cosmic dust could help explain why there is so much water in deep space.
In 1998, Cambridge Display Technology
(CDT), a company formed to commercialise organic light emitting diode (OLED) technology, announced it was planning to develop a full-size flat-plastic colour display in collaboration with Seiko-Epson.
The company’s portfolio and vision attracted investments from the rock band
Genesis, technology venture capitalist
Herman Hauser and Lord Young.
Interviewed in 1998, Dr Andrew Holmes, a co-founder of Cambridge Display
EPSRC 1994-2014
Technology, said: “There are so many applications for this technology, from displays on mobile phones or video recorders to sophisticated, full-colour flatpanel displays.
“I believe this will eventually result in a quantum leap in opportunities for this technology. It is going to change the way we do things.”
In 2000, the partnership with
Seiko-Epson led to the world’s first full colour active matrix inkjet printed polymer LED display.
It measured around five square centimetres and was just two millimetres thick.
In 2007, CDT was acquired by long-term collaborator Sumitomo
Chemical Company and in 2011 it was valued at £21 million.
In 2010, Cambridge Display
Technology, whose co-founders include Professor Sir Richard Friend (see page 32) and Professor Donal Bradley, won a prestigious Technology & Innovation
Award from The Engineer magazine for a project to create high quality white light using polymer organic LEDs (P-OLEDs).
Today, CDT is a world leader in the research, development and commercialisation of P-OLED technologies.
Among many potential applications these technologies could result in cheaper, brighter, clearer displays with wide viewing angles and ultra-fast response times.
In 1998, Dr Steve Rothberg and colleagues
Alan Hockwell and Jeremy Coupland,
EPSRC-supported researchers from
Loughborough University, won a major prize at the Metrology for World Class
Manufacturing Awards.
Metrology, loosely described as the science of measurement and application, is crucial to everything we do – from determining the amount of fuel in a tank to measuring the length of a piece of wood. It is crucial to manufacturing.
The Loughborough team won their award for the development of a new kind of laser measurement system that took the technology into new realms.
In the same year...
A team led by Professor Julian Jones at Heriot-Watt University developed an award-winning technique to control focus for laser welding. Laser welding, used across the manufacturing sector, requires highly precise tolerances, typically within an accuracy of plus or minus 1mm.
Heriot-Watt’s Dr Duncan Hand and Dr
Frank Haran played a key role in the project. Together they realised it was possible to use the light emitted by the welding process itself as a basis for gauging if the laser is in focus.
The research team’s breakthrough, in collaboration with industrial partner
Lumonics UK, was largely made possible by the EPSRC-funded Laser Engineering
Manufacturing Applications initiative involving research groups at Heriot-Watt and Liverpool University.
Today, Professor Julian Jones is Vice-
Principal of Heriot-Watt University;
Duncan Hand is Director of the EPSRC
Centre for Innovative Manufacturing in Laser-based Production Processes at Heriot-Watt; and Frank Haran is
Senior Engineering Manager, Honeywell
Process Solutions, Canada.
December 10, Sir John Pople, who spent his career in the United States, wins the Nobel Prize in Chemistry
27

1999
In 1999, Professor
Mike Brady, from the
University of Oxford, launched start-up company, Mirada, to commercialise his
EPSRC-supported research into medical imaging.
In 2001, further spin-out activity involving two of Professor
Brady’s companies led to the launch of
Mirada Solutions, which became a leading developer of software solutions and analytical tools for medical imaging.
In 2003, Mirada Solutions was acquired by CTI Molecular Imaging for $22 million, and in 2005 was purchased by
Siemens Healthcare.
In 2008, following a management buyout, which included acquisition of the technologies and customer base at the core of Mirada’s earlier developments, the company relocated to Oxford. Now Mirada
Medical, it is a prominent global brand in medical imaging software. Professor Brady is a non-executive director.
The success of Mirada is just one chapter in a remarkable story of innovation and evolution for Professor Brady, who has had a hugely successful research career ranging from developing automated sensor-guided vehicles to the detection of breast cancer.
In the 1980s Professor Brady founded
MIT’s world-famous robots laboratory before going on to lead the Robotics
Research Laboratory at Oxford, developing innovations such as collision-avoidance in robots.
He formed his first spin out company,
Guidance Control Systems (GCS), in 1991 to commercialise EPSRC-supported research at the robotics lab. In 2006, GCS, which provides navigation and positioning products and services, received a Queen’s
Award for export achievement.
In 1995, Professor Brady’s career took a sharp turn, when he moved into medical imaging.
From 2001 to 2003, Professor Brady was Director of the EPSRC/MRC
Interdisciplinary Research Centre in medical imaging and signals at the
University of Oxford (see page 35), and in
2002 he helped create the programme for the Life Sciences Interface Doctoral
Training Centre at Oxford, a new initiative to train the interdisciplinary researchers of tomorrow.
In 2004, Professor Brady was knighted for his services to engineering. He continues to play a key role in breakthroughs in image analysis, working with new technologies and techniques such as positron emission tomography, MRI and computer tomography (3D X-rays), which have revolutionised the way we look inside our bodies.
In one EPSRC-supported project, he developed a mathematical physical model of the passage of X-rays through tissue to explain the creation of a mammogram. This enabled the matching of one mammogram against another – a major step forward in the early detection of breast cancer.
Professor Brady’s entrepreneurial flair includes both the creation of spin out companies, and activities devoted to the commercialisation of science. For many years he served on the board of Isis
Innovation, which manages technology transfer and academic consulting for the
University of Oxford.
Today, Professor Brady, who has received over 30 EPSRC grants during his career, leads the Department of Oncological
Imaging at the University of Oxford.
EPSRC 1994-2014 January 1: The Euro currency is introduced
28

EPSRC 1994-2014 January 23: Nikon launches its D1 three megapixel digital SLR camera, costing US$6,000
29

1999
and laser sciences for generic non-invasive healthcare therapies.
In 1999, the foundations were laid for the cross-Research Council Basic Technology
Programme, led by EPSRC. The aim of the programme was to give technology research the same status as scientific research, and to develop new technologies with the potential to be adapted across all areas of science, ultimately leading to new industries of the future.
In 2010, Professor Dholakia’s team developed a new method to create minute self-healing holes in cell membranes to enable targeted drug delivery to cells and tissue at will. out company, Cortexica Vision Systems, in 1999.
Launched with the help of Imperial
Innovations, Cortexica pioneered visual imaging technology that mimics the way the human brain identifies images – resulting in an app-based product range that goes from strength to strength, including fashion, shoe and accessory search apps. The 10-year programme resulted in over
50 funded projects with a total investment of over £165 million. From April 2005, the programme was solely funded by EPSRC.
Interviewed in 2010, Dr Gunn-Moore said:
“As a biologist I never thought I would end up working in the physics world. This work came from a chance conversation with Kishan.
It truly is amazing that the light syringe we created has come so far so fast, and we are able to perform experiments we never thought would be possible four years ago.”
Because science is essentially convergent, bringing many methods together to answer a single question, while technology is more divergent (in that it can be applied in many fields), the Basic Technology
Programme focused on supporting risky new technologies of wide application.
In 2012, Professor Dholakia was awarded a £4.5 million EPSRC Programme Grant to ‘Challenge the Limits of Photonics’. The investment is one of many EPSRC grants he has received since 1999, as he helps pioneer a new scientific field.
Another project funded under the initiative saw £7 million invested in far-reaching research led by Professor Tom McLeish at Durham University to unlock the full potential of plastics. The project was part of what became a successful 20-year collaboration between academics and industry experts to explore how better to build ‘macromolecules’ – the basic components of plastics.
The programme’s many highlights included a four-year 2006 project led by physicist
Professor Kishan Dholakia at the University of St Andrews, working alongside biologist
Dr Frank Gunn-Moore, also from the
University of St Andrews, which resulted in breakthroughs in the use of ultrasound
EPSRC 1994-2014
Another project, led by the late Professor
Maria Petrou, from Imperial College
London, demonstrated the true ethos of Basic Technology; with fundamental science progressing to technology development and on to formation of a spin
February 12: President Bill Clinton is acquitted by the United States Senate in his impeachment trial
In 2011, Professor McLeish and his team made a breakthrough that should ultimately allow experts to create the
‘perfect’ plastic with specific uses and properties by using a high-tech recipe book. It will also increase our ability to recycle plastics.
30

He said it
Industry needs doctoral-level recruits who are adaptable and active right from day one so that they can fit in with team objectives. They must be able to talk about what they can do and communicate their skills to people who come from different disciplines.
The late Professor Tony Ledwith, EPSRC’s second chairman, interviewed in 1999. With a background in industry, Professor Ledwith, a former president of the Royal Society of Chemistry, emphasised the importance of building closer academic/industrial ties – which EPSRC champions to this day.
In 2011, in keeping with its commitment to ensure doctoral level recruits are given the opportunities they need to flourish in industry, EPSRC commissioned a major independent survey of leading research-intensive companies on the economic and social impact of PhD-holders they had recruited.
The survey, the first of its kind, involved
86 of the UK’s largest researchintensive companies, including Airbus,
Augusta Westland, Jaguar Land Rover,
Rolls-Royce, Unilever and Vodafone.
Among its many findings, the study showed that:
• 83% of employers said PhD holders had improved the company’s position relative to competitors
• 60% said PhD recruits are integral to commercial success
• 63% actively target PhDs when recruiting
• 74% said PhD recruits achieve high impact results within two years of joining
• 66% targeted PhD recruits with industry experience
• 92% of PhD recruits get up to speed more quickly after joining compared to graduates
• 73% highly rate PhD recruits’ influence on standards and good practice
Around 33 per cent of all doctorate holders whose PhDs and related doctoral qualifications were supported by EPSRC continue into academia, while nearly half find employment in business and public services.
Manufacturers, finance and IT companies are the biggest employers of doctoral graduates in engineering and physical sciences, representing around
75 per cent of those going into industry and public services. In addition, these sectors contribute nearly one third of
Gross Value Added to the UK.
In 1999, Professor
Mohammed Sarwar, from the University of Northumbria at Newcastle, led new research that culminated in significant improvements in the production of glass containers.
Working with industrial container manufacturer
PLM Redfearn, the research team found a way to reduce the weight of some glass containers by 33 per cent without compromising quality or strength.
A further benefit was that the process had a consequent effect on energy consumed during manufacture and transportation.
Many new technological innovations stand or fall on the precision of their engineering.
For example, mirrors and lenses used in space programmes must have nearperfect lenses; and for the next generation of car engines improved fuel efficiency and reduced emissions will depend on components that have been engineered to minute tolerances.
To achieve precise nanoscale surface specifications, in 1999 an EPSRCsupported team at Cranfield University, led by Professor John Corbett, developed a new breed of machine tool, dubbed Tetraform C, based on a tetrahedral frame.
Interviewed in 1999, Professor Corbett said: “We need tools capable of producing ever-higher tolerances – repeatedly. And for ultra-precision engineering we need ultra-stiff structures. The tetrahedron is one of the stiffest geometries known, because of its high symmetry and ‘closed loop’ form.”
The Cranfield team’s tool achieved worldrecord stiffness, enabling it to grind brittle materials such as glass and ceramics in a
‘ductile’ fashion.
The benefits of ultra-precision machines such as these are already feeding directly into many important areas of technology, from the manufacture of more reliable car engines to making silicon integrated circuits with nanometric accuracy and repeatability.
EPSRC 1994-2014
December 31: Boris Yeltsin resigns as President of Russia, leaving Prime Minister Vladimir Putin as the acting President
31

2000
In 2000, Professor
Richard Friend
(pictured), Professor
Henning Sirringhaus and Stuart Evans formed Plastic Logic
Ltd to commercialise their EPSRCsupported research at the University of Cambridge’s
Cavendish Laboratory.
The company’s formation built on the team’s 1989 invention of polymer organic light-emitting diodes (P-OLEDs), developed with colleagues at the university’s chemistry department and with EPSRC funding. Their genius spawned an entirely new industry – plastic electronics – and the subsequent creation of a new research field where plastics are made to emit light.
Plastic Logic was the first to fully industrialise the mass production of plastic electronics in the world’s first factory dedicated to the technology, achieving production yields of plastic electronic displays comparable to the LCD industry.
With a host of potential applications – from flexible electronic displays and paper-thin tablet computers, to ultra-efficient lighting and low-cost, long-life solar cells – it is estimated the global market for plastic electronics will grow to over £80 billion by 2020. The research also created manufacturing processes that combine the power of electronics with the pervasiveness of printing.
The story since has been one of constant achievement, supported by EPSRC through research grants and dedicated manufacturing and innovation centres focused on plastic electronics, large area electronics and related research.
Since 2009, the Technology Strategy Board has invested some £40 million, unlocking more than £100 million of R&D activity, including academic research into new plastic electronics technologies.
In 2007, the EPSRC-funded Cambridge
Innovation and Knowledge Centre (CIKC) in Advance Manufacturing Technologies for Photonics and Electronics was launched, providing additional support for Professor Friend’s research team and other innovators in the field. This was complemented in 2013 by the EPSRC
Centre for Innovative Manufacturing in
Large-Area Electronics, also at Cambridge.
In 2009, Plastic Logic and electronic display spin out company Liquavista collaborated on a project to develop flexible electronic displays that support full colour and video
– allowing products such as electronic newspapers that can show moving images.
In 2010, Professor Sir Richard Friend, who was knighted in 2003, Professor
Neil Greenham and Professor Henning
Sirringhaus co-founded Eight-19 Ltd to develop organic solar cell technology for manufacture. The company’s unique proposition includes off-grid pay-as-yougo-style mobile phone technology for the developing world – powered by solar cells based on printed plastic.
Eight-19 was formed to commercialise technology developed at the CIKC in
Advance Manufacturing Technologies for Photonics and Electronics, one of seven EPSRC-supported Innovation and
Knowledge Centres focused on facilitating the commercial exploitation of academic science and technology in partnership with industry.
In 2011, Plastic Logic announced a major
US$700 million investment from Russia’s
RUSNANO, focusing on building a massproduction factory for thin, light and flexible plastic-based e-paper displays.
In 2012, Professor Sir Richard Friend joined
EPSRC’s Council, the senior decisionmaking body responsible for determining
EPSRC policy, priorities and strategy.
In 2012, Eight-19 was crowned Small
Business of the Year and won the
Renewable Energy Project of the Year award at the BusinessGreen Leaders
Awards for its work on the Indigo pay-asyou-go solar system.
In 2013, The University of Cambridge’s
EPSRC-supported Graphene Centre signed a research collaboration agreement with
Plastic Logic on graphene in flexible plastic electronics. A major element of the agreement is to develop ‘wonder material’ graphene as a transparent, conductive layer for plastic backplanes for unbreakable LCD and flexible OLED displays.
In 2013, Plastic Logic joined forces with
Intel® and Queen’s University Belfast to develop Papertab, a flexible, 10.7” plastic touchscreen tablet resembling a sheet of paper. Stuff magazine named Papertab its Innovation of the Year at its 2013
Gadget Awards.
In 2013, the Plastic Electronics Leadership
Group revealed that the UK sector involved
33 universities and 134 companies; had generated annual revenues of £234 million; and employed 1,950 people in industry and
575 in academia.
Professor Friend says: “EPSRC was quick to provide critical support at the start of our research and has since been effective in funding the UK community across chemistry, physics and engineering, so that the UK community has been consistently world-leading.”
EPSRC 1994-2014 January 6: US students Jerry Yang and David Filo launch Yahoo

EPSRC 1994-2014 May 4: Ken Livingstone becomes the first Mayor of London

2000
In 2000, a ground-breaking strategic partnership in combinatorial chemistry with UK pharmaceutical giant Glaxo
Wellcome (now GSK) resulted in joint funding for 10 state-of-the-art mass spectrometers in UK universities – and marked the beginning of an enduring, highly productive relationship with GSK.
It was the first of EPSRC’s flagship
Strategic Partnerships with major companies and other research funders and users; providing access to world-leading knowledge, highly-trained people and high specification equipment that is directly utilised by industry. development, and provided the UK with an internationally-leading capability hitherto unavailable either in UK universities or in industry.
Subsequent EPSRC/GSK investments included installation of new analytical equipment at the universities of
Southampton and Swansea, open to industry and academics alike.
In 2008, EPSRC and GSK co-invested in a five-year, £10 million drug discovery and development project. within GSK such that our chemists now think more broadly about the scientific challenges they are attempting to address.
“Our strategic partnership has stimulated areas of research within academia and, conversely, has introduced new ideas to the industrial chemists through two-way exchange of information.”
Today, EPSRC’s portfolio of Strategic
Partnerships includes a range of international blue chip industries including BAE Systems, Rolls-Royce,
Procter & Gamble, Jaguar Land Rover, and, more recently, Tata Steel in 2014.
Over 40 per cent of the research supported by EPSRC is collaborative with industry.
The new partnership accelerated the UK pharmaceutical sector’s understanding of combinatorial technologies, helped advance analytical processes used in drug
In 2012, the two organisations announced they would jointly support a department
(chair) in sustainable chemistry at the
University of Nottingham.
GSK’s Director of Academic Liaison, Dr
Malcolm Skingle, says: “Working with
EPSRC changed the cultural mind-set
You can find out more about EPSRC’s
Strategic Partnerships in Pioneer 13.
34
EPSRC 1994-2014 June 19: Tiger Woods wins golf’s US Open by 15 shots, a record for all majors

In 2000, EPSRC co-invested £50 million in five new Interdisciplinary Research
Collaborations (IRCs) focused on new applications for information technology, computer science and communications in businesses, homes and hospitals.
The investment saw the creation of five university-based centres and marked a step change in how interdisciplinary research is facilitated and fostered, through long-term academic/industry collaborations.
Four of the new IRCs, funded in full by
EPSRC, tackled issues such as developing ultra-fast communications using optical technology; embedding computers into everyday objects and environments; improving knowledge management to prevent information overload; and improving the dependability of computerbased systems.
The fifth IRC, funded by EPSRC and the
Medical Research Council, examined how to transform medical images and data into useable clinical information.
Twenty universities and over 40 companies were involved in the new IRCs, which also brought to the fore the leadership talents and innovative research capabilities of the centres’ directors: Professor Sir Nigel
Shadbolt (knowledge management);
Professor Tom Rodden (embedded computing); Professor Wilson Sibbett
(optics); Professor Cliff Jones (computer system dependability); and Professor
Mike Brady and Professor Dave Hawkes
(medical imaging), all of whom have made pioneering contributions in their respective fields.
Interdisciplinary Research
Collaborations (IRCs)
EPSRC Interdisciplinary Research
Collaborations (IRCs) are centres of internationally-acknowledged scientific and technological excellence, with sufficient critical mass to make a significant impact in areas of key future industrial relevance to the UK.
IRCs generally involve several universities together with industrial partners, and are funded through large, long-term grants, typically around £10 million over six years.
Recent investments include IRCs in
Early-Warning Sensing Systems for
Infectious Diseases; Bionanotechnology;
Tissue Engineering; Quantum Information
Processing and Ultrafast Photonics.
In 2000, University of
Surrey-based EPSRC
Advanced Research
Fellow, Professor Adrian
Hilton, developed new computer imaging technology that allowed internet users to create much more
‘lifelike’ models of themselves.
Able to walk, run and jump, these avatars, which could be imported into computergenerated scenes using standard 3D modelling packages, gave users a clearer impression of whom they are dealing with online, and thus enhanced internet safety.
In 2003, Professor Hilton (pictured) was awarded a five-year EPSRC Platform Grant to develop his research into Visual Media, and to build a team to pursue long-term research in visual content production, interaction and information retrieval.
In 2009, the research, which included a project to develop 3D representations of real faces for realistic animation, was followed by a second five-year EPSRC
Platform Grant.
In 2013, Professor Hilton, now Director of the Centre for Vision, Speech & Signal
Between 2000 and 2003, EPSRC-funded research at the University of Sussex led to major improvements in the longevity and safety of the Advanced Gas-cooled
Reactors (AGRs) which currently provide about 75 per cent of the UK’s nuclear energy generating capability.
Estimates at the time suggested that if the
14 UK operating AGRs closed unnecessarily early, it could lead to losses running into billions of pounds, threaten the UK’s carbon dioxide emission targets and widen the nation’s energy deficit.
The research also informed the scale of the decommissioning process required for the first generation
Magnox reactors.
Processing (CVSSP) at the University of
Surrey, together with members of his team, co-developed a web-based system that could revolutionise the way we shop for clothes online.
The software they developed takes detailed measurements of the shopper’s body via a personal web-cam. Whether shoppers are pear, apple or hourglass-shaped the new software makes it easier for them to order the correct size.
The software, co-developed with London
College of Fashion, Bodymetrics and digital creative agency Guided, works like a virtual tape measure, taking accurate measurements and advising the user on which size garment to buy on a participating retailer’s website. A launch of the system is anticipated within two years.
Also in 2013, Professor Hilton received a five-year EPSRC Programme Grant to pioneer a new-generation 3D sound system which creates the live concert or sports experience from the comfort of the listener’s living room.
The programme is in collaboration with the universities of Southampton and Salford, the BBC and UK industry.
EPSRC 1994-2014 July 25: An Air France Concorde supersonic passenger jet crashes just after take-off from Paris, killing all 109 aboard and four on the ground
35

2001
In 2001, British manufacturing received a boost with the launch of 12 EPSRC
Innovative Manufacturing Research Centres
(IMRCs). The centres were the first in a series of investments focused on getting more science and technology out of the lab and into the factory.
Each IMRC built on work already being done in areas such as rapid prototyping; e-business; recyclable materials and modular construction methods.
During the programme’s 10-year lifespan,
15 separate IMRCs were launched, each addressing a series of manufacturing challenges.
EPSRC invested a total of £192 million in the centres, supplemented by
£207 million in industrial support from over 700 collaborators.
By 2011, the programme had created over 1,300 doctoral level manufacturing engineers. It had also created 160 new jobs; safeguarded a further 230 jobs and brought
20 new technologies to market.
Laser focus
One of the centres, based at Heriot-Watt
University, pioneered the development of revolutionary planar waveguide CO
2 lasers, in collaboration with research groups at the University of Hull and industrial partner
Rofin-Sinar UK.
Now manufactured by major international companies for applications in industry and medicine, including glass patterning, fabric decoration, and inscribing date codes on consumer products, global sales of these advanced laser products now exceed
US$1 billion.
Another project, at the University of Bath’s
Innovative Design and Manufacturing
Research Centre, led to the development of greener, faster and more efficient food packaging processes.
In collaboration with an independent food and drinks research centre and industrial partners, the team developed an improved
‘form-fill and seal’ food packaging process for foods such as rice, confectionery, pasta and crisps.
Project leader, Dr Ben Hicks, says: “The project has shown that reducing costs and saving the planet can go hand-in-hand.
“Using the lessons learned from this research, 39,000 tonnes of waste could be diverted from landfill per year. Based on the current level of landfill tax, this would save
£1.9 million in taxation alone.”
EPSRC 1994-2014 September 11: Two passenger planes hijacked by terrorists crash into New York’s World Trade Center causing the death of 2,752 people
36

EPSRC 1994-2014 October 7: The US invasion of Afghanistan starts with an air assault and covert ground operations
37

2001
In 2001, Dr Eric
Yeatman, Professor
Richard Syms and
Dr Andrew Holmes, from Imperial
College London, cofounded Microsaic
Systems plc to take their EPSRCsupported research to market.
The company’s core product was a desksized mass spectrometer instrument that can measure the masses and relative concentrations of atoms and molecules in substances.
The device was based on micro-electromechanical systems (MEMS) technology developed at Imperial.
MEMS is a technology that uses integrated circuit methods to produce tiny mechanical devices such as sensors, valves, gears, mirrors, and actuators in the form of semiconductor chips.
MEMS devices generally range in size from 20 micrometres (20 millionths of a metre) to a millimetre, and usually consist of a central unit that processes data, and components such as micro-sensors that interact with the surroundings.
In the 1990s, Dr (later Professor) Yeatman
(pictured) co-founded one of the UK’s first research groups into micro-electromechanical systems at Imperial, helping position the university as a world leader in the field.
In the 2000s, Microsaic went on to develop and market a range of next-generation mass spectrometry (MS) instruments for the analysis of gaseous, liquid and solid samples.
A key feature of Microsaic’s MS systems is that they are much smaller, consume less energy, and have lower running costs than conventional instruments.
EPSRC support for Professor Yeatman’s work has included successive Platform
Grants, enabling him to co-invent a number of new research methods and help position
Imperial College London as a world leader in the field of MEMS and related technologies.
In 2011, Microsaic was admitted to the
London Stock Exchange. In the same year,
Professor Yeatman, who was the company’s chairman throughout the 2000s, was awarded the Royal Academy of Engineering
Silver Medal. He was made a Fellow of the Academy in 2012, and through the
Academy acts as mentor to several young academic entrepreneurs.
Also in 2011, Professor Yeatman became co-director of the Digital Economy Lab at Imperial College London. He is also principal investigator of the Lab’s flagship project Digital City Exchange.
The Digital City Exchange is a five-year multidisciplinary research programme where researchers are exploring ways to digitally link utilities and services within a city, enabling new technical and business opportunities. The programme is funded by the RCUK Digital Economy Programme, led by EPSRC.
Professor Yeatman has acted as a design consultant for several international companies, and as technical advisory board member to two venture capital funds.
Today, Professor Yeatman’s research interests are in energy sources for wireless devices, radio frequency and photonic
MEMS, and sensor networks.
Professor Yeatman says: “High value-added technology products such as scientific instruments are an area where the UK can and does have a strong competitive position internationally.
“EPSRC support is a vital enabler of the developments underpinning this strategically important research field.”
38
EPSRC 1994-2014 October 23: Apple releases the iPod

In the fast-changing world of smart consumer electronics, in 2001 a team of computer experts from Imperial College
London, Jeff Kramer, Jeff Magee and
Naranker Dulay, developed a new computer language that enables manufacturers to keep reusing software components in products at no extra development cost.
Working with software architects at
Phillips, the team customised the system for electronic products. Interviewed in 2001,
Professor Magee said: “The previous way that TV sets were built gave much less flexibility and involved much more rewriting of software.”
Phillips deployed 300 of its software engineers to work on the system, leading to commercial success.
In 2001, Dr Serpil Acar, a Loughborough
University-based specialist in engineering design for women, and in mathematical modelling of the spine, began a three-year
EPSRC-supported project to develop a new seatbelt for pregnant women.
Working with car makers Jaguar, Ford and
Nissan, over the next decade Dr Acar’s
SeatbeltPlus project evolved into an awardwinning patented design. A prototype was developed at Loughborough and tested in specialist crash test laboratories.
Today, Dr Acar is founder of the
Biomechanics and Injury Prevention research group at Loughborough and also leads the Interdisciplinary Computing
Research Division. The Loughborough team are now in discussion with commercial partners to bring SeatbeltPlus to market. It could retail for as little as £10.
In 2001, after extensive consultation with the research community, EPSRC introduced a new initiative, Doctoral
Training Accounts (DTAs), which offered a more flexible approach in the way it funds doctoral training by passing the funds to universities to allocate rather than issuing them direct to students.
The new DTAs opened up a wide range of options in the way funds were used to achieve the high quality of student training demanded in an increasingly competitive doctoral training market.
EPSRC required universities to make commitments relating to the quality of supervision offered to doctoral students. It also expected students to receive broadening skills.
In 2014, the Doctoral Training
Account was renamed across all seven UK Research Councils as
Doctoral Training Partnership (DTP) but still retains its flexible approach in return for high quality doctoral training from universities.
EPSRC 1994-2014
In 2001, Cardiff University researcher Dr John
Culling developed a low-cost hearing test that can be done in the home to help people detect hearing loss earlier. The test worked by measuring a person’s ability to pick out conversation from background noise and on standard audio equipment.
In 2010, Dr Colling developed innovative sound-mapping software based on human hearing to help architects design out unwanted noise. The maps showed hotspots where conversations would not be intelligible if the room were busy. Architects can then adjust their designs to reduce reverberation until the hotspots are eliminated and audibility is maximised.
The new software is intended to be used in conjunction with standard architectural computer programs widely employed in room design. The research could also help in the future development of hearing aids and cochlear implants.
October 25: Windows XP is released
39

2001
In 2001, Alex Parfitt, an EPSRC-supported
PhD student at the University of Bath, working with a team led by Professor
Julian Vincent, used mechanisms found in nature to devise an adaptive deployable camouflage system for the Ministry of
Defence, which co-funded the project.
The team developed a gel that mimics the ability of cuttlefish to blend into their surroundings.
Interviewed in 2001, Parfitt, a postgraduate biologist in the university’s department of mechanical engineering, said: “The beauty of the cuttlefish system is that it uses the light surrounding the fish to camouflage it.
“Because the idea has come from biology, it is a reliable, low-energy system. We have developed a gel-based system that mimics this behaviour and are applying it as a cover for camouflaging large military vehicles.”
In 2003, Alex Parfitt joined BAE Systems where he continued his work in bioinspired technology. A recent project saw the development of night sight technology inspired by the Xenos peckii fly, a tiny parasite that has 50 separate lenses in each of its raspberry-like eyes.
Each of the lenses produces a different image, which when meshed together forms a single panoramic view in the fly’s brain.
BAE Systems scientists have recreated this effect with bug-eye – a camera with nine lenses – and about the size of a mobile phone camera lens.
This digital device has 60 degrees of peripheral vision and is small and light enough to fit onto a helmet, which could help soldiers spot an enemy out of the corner of their eye and doubles their level of vision from previous equipment.
It has been suggested that the technology could be adapted for use in CCTV cameras able to survey a wide panorama of crowded spaces, or perhaps developed as a tool to help with keyhole surgery.
EPSRC 1994-2014 December 15: The Leaning Tower of Pisa reopens after 11 years and over £20,000,000 to fortify it, without fixing its famous lean
40

Interviewed in 2001,
John O’Reilly, EPSRC’s recently appointed chief executive, addressed an area of perennial concern for the research council that remains equally true today, commenting:
“One of our challenges is that the demand for research funding massively exceeds our ability to fund, and in many areas there are more good applications than we can fund…
“What we must do is ensure that our money goes into supporting the best research. But this does not mean the resources will be spread thin, with equal shares around – that is not the mode of operation of EPSRC, nor should it be.”
In 2001, Professor Christopher Whitehead and Dr David Glover, from the University of Manchester, co-founded Plasma Clean
Ltd to commercialise core technology
Professor Whitehead invented during his
EPSRC-funded research into plasmas.
Plasmas are sometimes described as the fourth state of matter after solids, liquids and gases. For example, the core of the sun is in a plasma state.
Professor Whitehead’s research led to plasma technology that can blast apart the chemicals responsible for the smell of decomposing waste.
Today, Plasma Clean is one of the country’s leading developers of commercial air purification solutions.
With a nationwide network of approved specialists, the company provides costeffective grease, odour and smoke control for a wide range of environments, including commercial kitchens, washrooms, food storage, public waiting areas, and food and commercial waste sites.
In 2001, EPSRC joined forces with the six other UK Research Councils in the three-phase £140 million e-Science
Programme, which it went on to lead.
The funding supported a range of projects designed to position British science at the forefront of research into computing technologies.
In 2005, the e-Science Core
Programme leader Professor Tony Hey became Microsoft’s Corporate Vice-
President of Technical Computing and, in 2011, Corporate Vice President of
Microsoft Research Connections.
EPSRC 1994-2014
In 2001, EPSRC Senior Fellow Laurence
Eaves won the prestigious Guthrie Medal and prize of the Institute of Physics.
In parallel with his work into quantum chaos, Eaves and his team studied how electrons can ‘tunnel’ through materials when a magnetic field is present. This led to the development of a new technique, magneto-tunnelling spectroscopy.
The technique provides physicists with a new way to measure the structure of low-dimensional semiconductor materials, such as quantum wells, which are at the heart of the modern semiconductor laser diodes used in telecommunications and
DVD players. It could also help in the development of the next generation of transistors and lasers (see page 27).
January 26: An earthquake hits Gujarat, India, causing more than 20,000 deaths
In 2001, Professor Bryan Woodward and
Dr Fadlee Rasid, from Loughborough
University, began development of a unique system which uses a mobile phone to transmit a person’s vital signs, including the complex ECG heart signal, to a hospital or clinic anywhere in the world.
The system enabled a doctor to observe remotely up to four different medical signals from a freely moving patient.
Signals that could be transmitted included
ECG, blood pressure, oxygen saturation and body temperature. The technology marked an important advance in telemedicine and is thought to be a world first.
41

2002
In 2002, Professor Dave Hawkes and and prostate. A 1992 SERC grant enabled
Professor Hawkes, with PhD student colleagues at King’s College London (KCL)
Derek Hill and postdoctoral student Daniel developed 3D medical imaging technology
Rueckert, to develop the widely used and that enabled surgeons to steer clear of vital highly cited image registration technology regions and yet still work close to them. that underpins much of this work.
During an operation it is essential that the
In 2003, Professor Hawkes became Director surgeon is aware of critical structures, of the EPSRC/MRC-funded Interdisciplinary blood vessels or nerve fibres that need to be
Research Collaboration on Medical Images avoided. By taking MRI and X-ray computed and Signals, a joint initiative between tomography scans of the patient pre-surgery,
University College London, Imperial College the team developed a 3D representation of
London, the University of Oxford and KCL.
the area that the surgeon could follow on a computer screen during surgery.
In 2004, Professor Hawkes co-founded IXICO
To avoid surgeons needing to glance between patient and screen, Professor Hawkes later co-devised with Dr Philip Edwards a way to insert 3D images into the surgical operating microscope’s field of view. The microscope displays the image just where the surgeon is looking, helping them ‘see through’ overlying tissue and visualise the exact area they plan to operate on. If the surgeon is searching for a tumour, for example, the image indicates how far away it is. The system became highly useful to neurosurgeons. to bring aspects of his research to market.
The CEO of this London Stock Exchangelisted company, which provides imaging solutions to the pharmaceutical industry, is
Derek Hill, his former PhD student.
In 2005, Professor Hawkes moved his team to UCL, forming the UCL Centre for Medical
Image Computing. He was awarded a fiveyear EPSRC Programme Grant in 2009.
Today, Professor Hawkes, who has led or co-investigated 39 EPSRC research grants since 1992, co-leads the EPSRC Centre for
Doctoral Training in Medical Imaging at UCL and also heads the university’s Centre for
Medical Image Computing. He is co-Director
The team have since made major advances in 3D modelling of soft tissues, developing novel treatments of the liver, breast, lung of the UCL/KCL Centre for Cancer Imaging funded by EPSRC and Cancer Research UK, and co-leader of an EPSRC/Wellcome Trust smart surgery project in liver surgery.
In June 2014, he was named as coinvestigator of a £10 million EPSRC/
Wellcome Trust project to develop instruments and visualisations to assist surgeons operating on the fetus for spinabifida and other congenital problems while still in the womb.
Professor Hawkes says: “EPSRC’s support over more than two decades has enabled me to build a significant research programme.
Most importantly, it led to other support that pushed several innovations through to clinical trial and commercialisation.
“This work has achieved wide-ranging impact in areas such as neurosurgery, the study of disease progression in dementia, image-guided biopsy and focal ablation – which is poised to significantly change the management of patients with prostate cancer.
“There is now a significant body of worldleading medical image computing research at
UCL, KCL, Imperial and Oxford that can trace its roots to the initial EPSRC investment.”
EPSRC 1994-2014 January 9: Michael Jackson receives the Artist of the Century award at the American Music Awards
42

In 2002, an EPSRC-supported team from the universities of Sheffield and the West of
England began work on a whiskered robot inspired by rodents. Interviewed in 2002,
Sheffield’s Professor Tony Prescott said:
“For most rodents, whiskers are at least as significant as eyes are to sighted humans.”
The robot was designed for use in environments hazardous to humans – such as natural disaster zones and fire sites – which are often cramped, full of dust and smoke, and offer limited visibility.
The team went on to develop SCRATCHbot, which ‘feels’ its way using rat-like whiskers, and subsequently won the 2009
Best of What’s New Award from Popular
Science magazine.
In 2012, the team’s next creation, Shrewbot, was inspired by the four-centimetre long
Etruscan shrew, one of the world’s tiniest mammals, and used ‘active touch’ rather than vision to navigate its environment.
In 2013, inspired by their rodent research,
Professor Prescott’s team developed a ‘tactile’ helmet, which could provide firefighters operating in challenging conditions with vital clues about their surroundings. The helmet was fitted with ultrasound sensors that detect the distances between the helmet and nearby walls or other obstacles; and was exhibited at the 2013 Gadget Show Live event.
In 2002, Professor Andrew
Zisserman and Professor Andrew
Fitzgibbon received an Emmy Award, the
US TV industry’s equivalent of an Oscar, for their work on Boujou, a 3D camera tracker used in special effects movies such as the Harry Potter and Lord of the
Rings franchises. Boujou was borne out of an EPSRC-funded research project at the University of Oxford’s Department of
Engineering in the 1990s.
Today, Andrew Fitzgibbon is a member of the Microsoft Research Group in
Cambridge. A recipient of a Silver Medal from the Royal Academy of Engineering, in 2013, he was a core contributor in the development of Kinect for Xbox 360.
Professor Andrew Zisserman is Principal
Investigator at the University of Oxford’s
Visual Geometry Group and a worldrenowned computer scientist.
He began his academic career as a member of Professor Mike Brady’s Oxford
Robotics Group in the 1980s (see page 28) and was made a Fellow of the Royal Society in 2007.
In 2002, EPSRC launched its first
Centres for Doctoral Training (CDTs).
What began as a pilot programme to support doctoral training in the life sciences evolved into a major initiative for training the interdisciplinary researchers of tomorrow in strategically important areas.
Such was the success of the early
CDTs, which evolved from EPSRC’s pioneering Engineering Doctorate initiative in the 1990s, there are now 115 centres spanning EPSRC’s portfolio.
CDTs bring together diverse areas of expertise to train engineers and scientists with the skills, knowledge and confidence to tackle today’s evolving issues. They also create new working cultures, build relationships between teams in universities and forge lasting links with industry.
CDT students receive a programme of taught coursework to develop and enhance their technical interdisciplinary knowledge, and broaden their set of skills. Alongside this programme they undertake a challenging and original research project at doctoral level.
Combined governmental and partner funding for CDTs is now £962 million, including £31 million in capital investment. It is the UK’s largest investment in postgraduate training, involving over 5,500 students in areas of key importance to the UK economy and society.
EPSRC 1994-2014 March 30: Queen Elizabeth The Queen Mother dies aged 101
43

2002
In 2002, Dr
Sam Kingman
(pictured), from the University of
Nottingham, made a breakthrough in his EPSRC-funded research into using microwave radiation to break up mineral-bearing rocks.
Traditional crushing and grinding of rocks to extract minerals is massively energy inefficient. Typically, only one per cent of the energy input into rock grinding actually causes size reduction.
Dr Kingman’s process uses bursts of microwave radiation to crumble the rock, prior to grinding.
Most rocks need just a fraction of a second to weaken them sufficiently before grinding, when they will fall apart easily. Rio Tinto, one of the world’s largest mining companies, supported the research from its outset.
In 2006, Professor Sam Kingman was awarded a personal chair at Nottingham, making him one of the youngest professors in the UK. He later became
Director of the National Centre for
Industrial Microwave Processing (NCIMP).
In December 2013, the University of
Nottingham and Rio Tinto agreed a
£6 million, five-year partnership to develop the next generation of innovative technologies for the mining industry.
The programme is centred around a new facility at Nottingham, the Rio Tinto
Centre for Emergent Technologies. Its
Research Director is Professor Kingman.
Engineers at the centre are researching new ways of separating ores based on the properties of individual rocks, meaning that waste material with no valuable minerals contained within it can be rejected prior to energy-intensive further processing.
Professor Kingman says: “Over 20 granted patents, 28 PhD students graduated, more than 80 journal papers published, and many tens of millions of pounds of industry investment across numerous sectors all across the world can all trace their roots to my EPSRC first grant project.
“Without the support of EPSRC, none of this would have happened, I am still to this day extremely appreciative of the support I have been given.”
EPSRC 1994-2014 October 30: Freeview television service begins transmitting in parts of the UK
44

In 2002, EPSRC-supported researchers at the University of Cambridge, led by
Dr David Aldridge, developed an elegant solution to the problems caused by freshwater zebra mussels, which are a major pest, clogging pipelines in water treatment works and power stations, and costing millions of pounds each year to remove.
The conventional solution is to poison the mussels with chlorine, but the team developed a greener, more targeted approach that neatly overcame one of chlorine’s major drawbacks – zebra mussels can taste it in the water and close their shells, surviving for three weeks before opening up again, meaning chlorine must persist over this time to be effective.
Working with Dr Geoff Moggridge from the
Department of Chemical Engineering at
Cambridge, the team developed a way to poison the mussels, 4cm-long creatures which lay up to 30,000 eggs per year, by tricking them into swallowing a dose of toxin packaged to resemble a pellet of food.
The research led to the formation of a spin out company, BioBullet, which developed potassium chlorine as the lethal ingredient.
Together with Bristol firm, TasteTech,
BioBullet developed a pellet that is both mussel-palatable and waterproof.
Interviewed in 2002, Dr Aldridge said: “The beauty is that we engineer the coating materials so that the pellet dissolves and degrades, and the entire product degrades within hours of going in the water.
“There’s also no impact on the wider biodiversity living in rivers and streams that might receive the outflow water.”
The research has been of great interest to the UK water industry, with at least four companies funding the research to date.
In 2010, following approval by the Drinking
Water Inspectorate, trials began with
Anglian Water Services Ltd to use the pellets in the UK for potable water systems.
In the same year, the company secured funding of £500,000 from the Technology
Strategy Board, match-funded by Anglian,
Thames Water and TasteTech.
In 2002,
Professor
Chris
Hull, a theoretical physicist from Imperial College London, was awarded the prestigious Dirac medal and prize by the Institute of Physics for his decade-long research into superstring and M-theory.
The prize followed an EPSRC
Senior Research Fellowship, awarded in 1996.
In 2012, Professor Hull was made a Fellow of the Royal Society.
In 2013, Professor Hull (pictured in 2002) was awarded an EPSRC
Programme Grant to lead research into new geometric structures from string theory, alongside co-investigators Jerome
Gauntlett, Amihay Hanany and
Daniel Waldram.
EPSRC 1994-2014
In 2002, Dr Mary Ryan from Imperial
College London and Professor David
Williams from University College London solved the mystery of why stainless steel can unexpectedly fail. The metal is not meant to corrode, but it can, and when it does the results can be disastrous, whether it’s a hole in your dishwasher or a failed industrial plant.
‘Stainlessness’ is created by alloying iron with chromium. As the steel ingot cools after it has been made, tiny sulphur-rich impurity particles, about 10 millionths of a metre in diameter, solidify at a lower temperature than the steel, remaining molten for a time after the metal has solidified.
Using an advanced new microscope the team found a region around the impurity particles with significantly less chromium than the rest of the steel.
During cooling of the steel the impurity particles ‘suck’ chromium out of the steel around them, creating a tiny nutshell of steel that is not stainless. Corrosion of this layer, just one 10 millionth of a metre thick, is enough to trigger the main attack.
In 2011, Professor Mary Ryan was awarded the Institute of Minerals, Materials and
Mining’s Rosenhain Medal and Prize in recognition of distinguished achievement in materials science for her outstanding contribution to applied electrochemistry and corrosion.
December 22: Joe Strummer, lead singer of the seminal British punk band The Clash, dies at age 50
45

In 2003, EPSRC assumed responsibility for the UK fusion programme, with £48 million in funding allocated via the Office of Science and Technology.
Fusion, the process by which the sun produces heat and light, has the potential to provide an almost limitless clean, safe, renewable energy source for future generations.
The EPSRC grant was awarded to the UK
Atomic Energy Authority at its Culham site in
Oxfordshire. The grant underpinned the UK’s involvement in the EURATOM Joint European
Torus (JET) project, also at Culham; the development of the UK’s own fusion device,
MAST; and research on the materials needed for a fusion power station.
Today the UK fusion programme is centred on the innovative MAST experiment and employs around 150 people. While the MAST remains the UK’s flagship programme, the UK continues to run JET and is also developing materials and technology facilities. The fusion programme as a whole employs around 1,000 people.
The fusion reactions that turn hydrogen into helium in the core of the sun produce a lot of energy and could be used as the basis for a power station on Earth. However, making this process efficient is difficult as additional energy is required to get the nuclei close enough to fuse together. Formidable engineering and scientific challenges need to be addressed.
One way of achieving fusion is to trap a plasma with a magnetic field and heat it up in a doughnut-shaped device called a tokamak. The JET programme at Culham is the world’s largest tokamak experiment.
The plasma in the centre of JET reaches temperatures of 100 million degrees, about
10 times hotter than the centre of the sun.
These high temperatures are not a safety concern because the amount of fuel inside the tokamak is extremely low, weighing about as much as a postage stamp.
In 1997, JET produced 16 mega watts of fusion power, a world record that still stands today, but 24 mega watts of heating power were needed to do this. Calculations predict a bigger tokamak is required to break even.
A new international tokamak experiment, called ITER, is under construction in
Cadarache, France. Three times bigger than JET, it is expected to produce 10 times more fusion power than heating power – considered proof that it is possible to build a viable fusion power station.
To match ITER’s designs, JET’s vessel walls have been changed from graphite to a combination of tungsten and beryllium. New results with these materials in place are helping scientists and engineers to prepare for ITER’s first operation in 2019.
In 2014, the Culham centre announced it will try to set a new world record in nuclear fusion by the end of the decade – when it plans to run JET at maximum power, and reach the coveted breakeven goal where fusion yields as much energy as it consumes.
Words: Jack Snape
Jack is an operational research analyst at the Department for Business, Innovation and Skills. He is a former EPSRC-sponsored
PhD student in Plasma Physics and Fusion
Energy at the University of York, and a
Postgraduate Fellow at the Parliamentary
Office of Science and Technology Education.
EPSRC 1994-2014
August 2003: Ground-breaking social networking website MySpace is launched – one year before Facebook
46

EPSRC 1994-2014
47

2003
In 2003, SUPERGEN, the UK’s flagship initiative in sustainable power generation and supply, was launched. The ambitious multidisciplinary research initiative, led by EPSRC, covers a vast green energy landscape, taking in areas such as climate change, fossil fuel extraction rates, emissions control, and increasing public awareness of environmental concerns.
SUPERGEN aims to contribute to the UK’s environmental emissions targets through a radical improvement in the sustainability of the UK’s power generation and supply.
Focusing on collaborative research projects between industry and academia, the initiative began with an investment of
£25 million in four consortia: Marine
Energy, Networks & Power Control,
Hydrogen Energy & Storage and Biomass
& Biofuels.
Over the next decade,
SUPERGEN, which stands for Sustainable
Power Generation and Supply, built into a network of eight consortia and six hubs, supported by over £100 million of investment, offering a major route for industry involvement in academic research.
As well as developing an array of technology now being furthered by the several dozen university departments involved, along with their numerous industrial partners, the consortia have broken new ground in the way they have approached their subjects. Rather than working on specific, discrete projects in isolation, the SUPERGEN projects look at entire topics; an approach which has led to expansion into areas such as extending the life of power plants, advanced photovoltaic materials and asset management.
An example of the benefits of this approach is research overseen by the Excitonic Solar
Cells Consortium. Tasked with developing a new class of solar cell based on organic materials, the consortium’s research inspired complementary technologies using the same low temperature processing techniques used to prepare flexible organic light emitting diodes.
At the University of Warwick, a
SUPERGEN-sponsored research team led by Professors
Tim Jones and Ross Hatton, working with Molecular Solar Ltd, a company they formed to commercialise their work, pioneered the development of a new type of flexible, organic solar cell.
Molecular Solar achieved a record voltage for the cell, which could soon be used in a wide range of consumer electronics – from e-readers to mobile phone chargers.
Centres flourishing under the SUPERGEN initiative include the UK Centre for Marine
Energy Research at Edinburgh University
(see page 9).
48
EPSRC 1994-2014 February 17: London introduces congestion charging

He said it
In 2003, Professor Peter Mansfield, from the University of Nottingham, and Paul
Lauterbur were awarded jointly the Nobel
Prize in Physiology or Medicine “for their discoveries concerning magnetic resonance imaging (MRI)”.
Since their launch in the 1980s, MRI scanners, which create detailed images of the body to assist in the diagnosis of medical conditions, have transformed diagnostic medicine and saved the lives of many thousands of people.
Despite being told at 15 he would never become a scientist as he had no qualifications, on leaving school Peter
Mansfield enrolled in evening classes to get the qualifications he needed.
He went on to secure a place at Queen
Mary, University of London – and never looked back, going on to develop rapid imaging techniques, thus facilitating images that can distinguish between healthy and cancerous tissue.
Now Emeritus Professor at the University of
Nottingham, Peter Mansfield has received
UK Research Council support throughout his career, including from EPSRC and its predecessor the Science and Engineering
Research Council (SERC).
Today, there are more than 20,000 MRI scanners globally, and over 70 million scans are performed each year.
The annual market value for the technology is estimated to exceed £5 billion by 2015.
So far I have been lucky only twice – with our gecko experiment and the one using diamagnetic levitation. So that’s once every five years.
According to these poor statistics I do not expect anything before 2008.
Fortunately, one cannot predict or plan even minor discoveries.
Professor Andre Geim, from The
University of Manchester, interviewed in 2003, on science that hits the media spotlight.
One year later, together with Dr
Konstantin Novoselov, Andre Geim made history by isolating ‘wonder material’ graphene. You can find out more about this remarkable breakthrough and its potential consequences on pages 50-53.
In 2010, Geim and Novoselov received the
Nobel Prize for their graphene research – and were made Knights of the Realm in 2011.
In 2003, a team of researchers at the
University of Birmingham’s School of
Manufacturing and Engineering designed and built a fully working single piston micro engine that could be balanced on the tip of your finger.
The project hit the mainstream news headlines – and saw team member Mike
Ward gracing Richard and Judy’s sofa at ITV to describe the team’s innovative research.
The idea behind the project was bold: that a micro engine powered by hydrocarbon fuel would have over 200 times the energy capacity of a typical battery.
Interviewed in 2003, Dr Kyle Jiang, who led the EPSRC-supported project, said: “If you ask a group of mobile phone users which part of the phone they dislike the most, 10 out of 10 will say the battery.
“What we realised was that a micro engine powered by a cartridge of fuel such as methane or propane could last 30 times longer than a mobile phone battery. So you might only need to charge the phone twice a year, not twice a week.”
EPSRC 1994-2014
He was, of course, speaking in the heady days before the advent of energy-sapping, daily-charging smartphones.
April 14: The Human Genome Project is completed with 99 per cent of the human genome sequenced to an accuracy of 99.99 per cent
49

2004
In 2004, EPSRC-funded research by
Professor Andre Geim and Dr Konstantin
Novoselov, from The University of
Manchester, led to the isolation of graphene, a material with many potentially world-changing applications.
Just six years later, Andre Geim (pictured below left) and Konstantin Novoselov were awarded the Nobel Prize in Physics for their graphene research. EPSRC has supported their research through continuous funding since 2001.
On the same day they received the award, both men were back in their lab, continuing to unveil new and exciting properties of graphene and other related twodimensional crystal materials.
If you’ve ever drawn with a pencil, you’ve probably made graphene, which consists of a sheet of carbon atoms connected in a honeycomb-like structure.
At just one atom thick, no material is thinner than graphene. It’s also harder than diamond and 200 times tougher than steel
– yet can be stretched by a quarter of its length.
Graphene also has extraordinary properties as an electrical and thermal conductor, and almost complete optical transparency, making it potentially suitable for a host of commercial applications – from lightweight materials for aircraft, cars and clothing, to flexible, super-tough touchscreens for mobile phones and tablets (already under development); and from water purification to next-generation low energy computers.
Geim recalls the momentous days back in
2004 when he and his team, including Dr
Novoselov, then a postdoctoral researcher, successfully extracted individual sheets of carbon atoms from bulk graphite – the material pencils are made from.
True to the two scientists’ reputation for innovative thinking, they used sticky tape to strip the graphite down to the atomic level.
Although scientists knew graphene existed
(it was first studied in 1947, and named in 1987), no one had worked out how to extract it from graphite.
(Continued on page 52)
Double act: Andre Geim and Konstantin Novoselov.
Their isolation of graphene and subsequent graphenerelated research led to the Nobel Prize in Physics in
2010 and Knighthoods in 2011.
EPSRC 1994-2014 April 2: St Mary Axe, otherwise known as the Gherkin, is officially opened in the City of London
50

EPSRC 1994-2014 February 4: Facebook is launched
51

2004
(Continued from page 50)
The breakthrough came during one of
Geim and Novoselov’s now legendary
Friday evening sessions, when they head into the lab to try out experimental science not necessarily linked to their day jobs.
This playful approach is fundamental to how both men work, and is seen as both a useful way of maintaining interest in a field and a means of generating new ideas.
Following discussions with colleagues,
Geim and Novoselov adopted a method that researchers in surface science were using
– using simple scotch tape to peel away layers of graphite to expose a clean surface for study under the microscope.
Once used, the tape was simply being thrown away. Yet no one had noticed the material on the tape was thinner than the material produced by polishing.
They had made graphene, yet had not realised it.
Konstantin Novoselov continued to explore how thin the graphite flakes on the tape could be made. He peeled the layers so thinly that what was left was one-atom thick graphene.
The pair then began testing the material under the microscope, beginning to take in the vast potential of its properties. They produced the first isolated graphene flakes in 2003 and published their findings in the journal Science in 2004.
Professor Geim says: “Our objective was simply to see how thin materials could be.
At the time, it was presumed materials one atom thick couldn’t exist. But our discovery of graphene proved this supposition wasn’t correct.”
EPSRC 1994-2014
News of graphene’s discovery sparked a global explosion in graphene research, which shows no sign of abating. The global market for graphene-based applications could potentially grow to tens of billions of pounds over the long term, in areas such as electronics, high-performance materials and life sciences.
In 2009, the website ScienceWatch.com revealed Dr Novoselov’s work on graphene as the most cited of the decade, with
33 academic papers quoted 2,895 times.
Geim and Novoselov, who received knighthoods in 2011, continue to push the boundaries of graphene, and its diverse potential applications.
In November 2014, they revealed in the journal Nature that monolayers of graphene, and its sister material boron nitride, could potentially revolutionise modern fuel cell technology. They also revealed that graphene membranes could be used to sieve hydrogen gas out of the atmosphere, where it is present in minute quantities, creating the possibility of electric generators powered by air.
In 2014, Geim and Novoselov’s original
Manchester graphene paper, which laid out the foundations of graphene research, was named among the top 100 cited publications of all time.
All this from two scientists “whose playfulness is one of their trademarks”, according to the Nobel committee.
Professor Novoselov says: “During our
Friday evening experiments I just do all kinds of crazy things that probably won’t pan out, but if they do…”
• Graphene is over 200 times tougher than steel
• Graphene is a far better conductor than silicon
• Electrons pass through graphene at over 100 million metres per second, behaving as if they have no mass
• Graphene is the thinnest material on earth – one million times thinner than a human hair
• Graphene is the world’s first 2D material, opening the doors to new, experimental fields
• As well as being virtually transparent, graphene is also flexible
• Next generation, low-energy computers
• Graphene paints, to protect metal structures against corrosion
• Super-fast internet speeds
• As lightweight materials for aircraft, cars and clothing
• Flexible touchscreens (already under development)
• High-frequency electronic devices
• Large scale electricity storage
• Lightweight durable batteries
• Development of other 2D materials with the potential to create previously-unimagined electronic devices
• Water filters for desalination and purification
• Nanoscale graphene-based drug packages delivered to specific cells in the body
• Packaging to keep food fresh for longer
• Sensors to detect minute traces of gases or dangerous chemicals
March 29: The Republic of Ireland becomes the first country in the world to ban smoking in all work places, including bars and restaurants
52

EPSRC has invested widely in graphene research and development since 2004.
In 2012, EPSRC advised the UK Government on its £50 million investment in the creation of a global research and technology hub.
Building on the UK’s research strengths in many universities and business, the hub concept was developed by EPSRC, the
Technology Strategy Board and academic and business stakeholders. It has also been supplemented by additional investments from EPSRC and Innovate UK (formerly the
Technology Strategy Board).
Key government investments in graphene:
• £38 million in the National Graphene
Institute (NGI) at The University of
Manchester to develop new production methods and techniques for largescale manufacture, application and commercialisation of graphene
• £12 million for graphene research equipment in other leading research groups across the UK
• £14 million for EPSRC-supported research into manufacturing processes and technologies linked to graphene
• Over £10 million of EPSRC support towards fundamental science in graphene and carbon nanotechnology
• £2.5 million jointly from EPSRC and Innovate UK to accelerate the commercial application of emerging graphene and related carbon-based nanotechnologies
• £15 million from the Higher Education
Funding Council for England (HEFCE) alongside £5 million support from Innovate UK to establish the Graphene
Engineering
Innovation Centre in Manchester
• £14 million of
Innovate UK funding for the Graphene
Applications
Innovation
Centre, based at the Centre for Process
Innovation, part of the High Value
Manufacturing Catapult, in Sedgefield
There are now over 35 active university groups in the UK, which have attracted over
£90 million in graphene-related EPSRC research grants and capital investment, as well as significant investment from Europe and industry.
Alongside The University of Manchester, there are EPSRC-supported centres of excellence and/or graphene programmes at the universities of Cambridge; Lancaster;
Imperial College London; Oxford; Bath;
Birmingham; Nottingham; Exeter; Surrey; and Durham.
2014 saw the launch of two EPSRC
Centres for Doctoral Training, based at the universities of Cambridge and Manchester, focusing on developing world-leading expertise in the science and technology of graphene.
Graphene engineering
Since 2012, EPSRC has invested £26 million in graphene engineering, which includes
£12 million from the Department of Business
Innovation and Skills.
The University of Cambridge has combined three of its Graphene Engineering EPSRC grant awards, totalling £12 million, to establish the Cambridge Graphene Centre, led by Professor Andrea Ferrari. The centre has attracted £13 million in additional support from over 20 partners, including
Nokia, Dyson, Plastic Logic, Philips and
BAE Systems.
The centre works alongside the Centre for
Advanced Photonics and Electronics and the new EPSRC Graphene NOWNANO Centre for
Doctoral Training in Graphene Technology at
The University of Manchester.
In 2013, the Cambridge Graphene Centre signed a research collaboration agreement with leading flexible plastic electronics manufacturer Plastic Logic. A major element of this agreement is to develop graphene as a transparent, conductive layer for plastic backplanes for unbreakable LCD and flexible
OLED displays.
EPSRC has invested £1.6 million in graphene engineering at Durham University and the
University of Sheffield. Industrial partners include Dyson Appliances Ltd, P&G UK and Applied Graphene Materials (AGM)
– a world leader in graphene production and applications, founded by EPSRC grant-holder Professor Karl Coleman at
Durham University.
EPSRC 1994-2014 September 1: Chechen terrorists take between 1,000 and 1,500 people hostage, mostly children, in a school in the Beslan school hostage crisis
53

2004
EPSRC 1994-2014 June 8: Transit of Venus between Earth and the Sun occurs
54

In 2004, John Pendry,
Professor of Theoretical
Solid State Physics at
Imperial College London, was knighted for his revolutionary work on metamaterials.
With EPSRC’s support, Sir John has established an entirely new field of science.
By developing and using certain materials that don’t occur in nature, he has shown that light can interact with structures that are smaller than its wavelength, making it possible to see even at the nano scale, and then harness the benefits that this insight brings.
The impetus for Sir John’s research came from work he was doing with the company
Marconi, attempting to understand why certain materials absorbed radar. But the new area of research that this led to has a huge range of potential applications in many different fields.
Professor Pendry’s research built on
EPSRC-supported work throughout the
1990s, including a 1997 Senior Research
Fellowship to further his work on ‘a new class of man-made materials with extraordinary optical properties’. He said later: “Having great ideas doesn’t involve excessive time. What does take time is working them through. That’s what EPSRC funding allowed me to do. It put a rocket under the metamaterials work.”
In 2000, Sir John published a number of papers developing ideas put forward in
1968 by the little-known physicist Victor
Veselago. The papers set out the theoretical basis for creating ‘perfect lenses’, which could be used to see things smaller than the wavelength of light.
Pendry’s perfect lens utilises what is known as negative refraction, and sidesteps old optical limits by bending rays of light the
‘wrong way’. In other words, the so-called
‘resolution limits’ once thought to restrict the range of things that we can examine through optical imaging need not apply.
In 2002, a second EPSRC Senior Research
Fellowship enabled Sir John to leave his post as Principal of Imperial’s Faculty of
Physical Sciences to pitch himself into fulltime research.
In 2006, metamaterials hit the headlines when Sir John published ideas for a
Harry Potter-style ‘invisibility cloak’.
Metamaterials could be used, he said, to send light around an object, making it look like it wasn’t there. Journalists have fixated on the story ever since.
In 2014, metamaterials are finding application across the electromagnetic and acoustic domains and are seen as an enabling technology of the future. Negative refraction could allow limitless computer data storage, and revolutionise biological imaging, nanofabrication and light harvesting. In theory, it could also lead to perfectly efficient solar panels.
Research into this emerging field has grown very rapidly. To date, EPSRC has invested over £130 million in over
90 projects related to metamaterials and photonic materials research.
At the University of Southampton, Professor
Nikolay Zheludev has a major EPSRC grant to develop artificial electromagnetic media with myriad potential applications in areas such as telecommunications, energy, data storage and defence.
Research into nanoscale-structured metamaterials by Professor Jeremy
Baumberg, from the University of
Cambridge, has revealed a host of novel and highly exploitable optical properties, for which he received the Royal Society
Mullard Prize.
Research at the University of Exeter, which hosts the new EPSRC-funded Centre for
Doctoral Training in Metamaterials, has led to breakthroughs in the design of thin radar absorbers and improved RF-ID tag detection; the team are also developing acoustic metamaterials to improve underwater imaging.
In 2014, Sir John Pendry was awarded the Kavli Prize, considered the Nobel
Prize in nanoscience, with Thomas
Ebbesen and Stefan Hell, in recognition of his ‘transformative contributions’ to nano-optics.
Sir John says: “Things have come full circle: my work on metamaterials began with attempts with Marconi to solve a practical problem. It then went theoretical, as we tried to explore the profound academic implications of what we were finding.
And now here we are again, with all kinds of practical applications coming from our research.”
Left: This striking abstract ‘sculpture’ is part of a nanoscale metamaterial with negative index due to chirality, from the
EPSRC-supported Optoelectronics Centre at the University of Southampton.
EPSRC 1994-2014 November2: In the US presidential election, incumbent President George W. Bush is declared the winner over his challenger, Senator John F. Kerry
55

2004
In 2004, Dr Sandy
Cochran (top left), from
Paisley University, was awarded an EPSRC
Advanced Research
Fellowship to explore new types of ultrasound source that might one day echo across our oceans or resonate in our bodies.
A series of EPSRC grants followed, including a
£5 million Platform Grant to develop
‘SonoPill’ technology.
The SonoPill is a capsule that patients can easily swallow to carry tiny ultrasound technology into the body. The gut is a wonderful viewing window and as the capsule passes through it, it will relay images which clinicians can use to diagnose disease.
Now at the University of Dundee, Professor
Cochran says: “So-called capsule endoscopes have already benefited well over a million patients and are in common use in the UK and around the world. We aim to develop that technology further to include ultrasound, for the first time seeing beyond the surface of the gastrointestinal tract into the tissue itself.
“This will bring significant diagnostic benefits for patients. We also want to explore the very exciting possibilities of treatment with such pills.”
The SonoPill programme includes very valuable collaborators at Heriot-Watt
University and the University of Glasgow, and is linked with the NHS and many local and international industry partners.
In its use of tiny, high performance ultrasound arrays and its exploration of therapeutic ultrasound, the SonoPill research forms a natural extension to the
UK-wide EPSRC-supported ‘Sonotweezers’ programme, involving the universities of
Bristol, Dundee, Glasgow and Southampton as well as other industry partners.
Following EPSRC funding, the
Sonotweezers programme is developing new tools for the life sciences and high value manufacturing using ultrasound to manipulate microparticles by electronic alteration of the patterns of ultrasonic excitation.
The team have already demonstrated that a ‘sonic lasso’ can be used to grip
EPSRC 1994-2014 July 17: Former South African President Nelson Mandela calls for commitment by the world to take action against Aids
56

microscopic objects, such as cells, and move them about; this has myriad possible applications, from assembly of nanocomposites to cell sorting and analysis, and engineering of human tissue from collection of cells.
In 2014, the Southampton Sonotweezers team helped to develop technology that could lead to life-changing medical advances, such as better cartilage implants that reduce the need for knee replacement operations.
Using ultrasonic sound fields, the team showed that cartilage cells taken from a patient’s knee can be levitated for weeks in a nutrient-rich fluid, providing a zerogravity environment perfect for optimising cell growth.
The tweezers can also mould the growing tissue into exactly the right shape so that the implant is truly fit-for-purpose when inserted into the patient’s knee.
Meanwhile, at the University of Glasgow…
In 2004, a team of EPSRC-supported researchers led by Professor Margaret
Lucas (pictured below left) began development of an integrated robotic orthopaedic surgery system incorporating an ultrasonic cutting blade that could consign the surgical saw to a museum.
Using conventional powered saws on bone causes many problems for patients and surgeons. For example, the action of the saw produces swarf – small pieces of bone
– that can reduce visibility at the cut site, create a risk of contamination, and damage delicate soft tissue structures around the cut. Also, heating from the sawing action causes cell death, which is known to prolong post-surgery healing.
The team’s research led to the development of ultrasonic cutting tools precise enough to remove sections from the shell of an egg without breaking the membrane underneath. Further EPSRC-funded projects allowed the group at the University of Glasgow to develop miniature ultrasonic orthopaedic devices incorporating novel transducers and smart materials.
In 2013, Professor Lucas, Professor
Cochran and colleagues at the University of Edinburgh were awarded a threeyear EPSRC research grant to develop a needle which is actuated by vibration at ultrasonic frequencies.
Amongst its many potential benefits, this will allow doctors to penetrate bone with needles with much less force than in contemporary procedures and with much higher precision, improving the effectiveness of bone biopsies and allowing more direct delivery of drugs to parts of the body obscured by bone.
In 2014, Professor Lucas and Dr Patrick
Harkness were awarded €2.4 million by the EU Commission to develop an ultrasonic drill to explore the surface of
Mars. The research builds on much of the basic knowledge gained from designing bone cutting devices and also builds on an earlier EPSRC-funded research programme led by Dr Harkness, who says:
“Unlike normal rotary drills, our ultrasonic drill tool doesn’t produce much heat – meaning that biological material and life markers will not be damaged.
“Because the drill only requires a very small downward force, it is ideal for use in low gravity environments such as Mars or on asteroids.”
EPSRC 1994-2014 August 22: Armed robbers steal Edvard Munch’s The Scream, Madonna, and other paintings from the Munch Museum in Oslo, Norway
57

2004
In 2004, an EPSRC-supported
Loughborough University research team took part in an innovative project to investigate whether African termite mounds could inspire new types of self-sufficient, environmentally friendly buildings which are also cheap to run.
the mound in a level of detail never achieved before.
The team discovered that termite mounds provide a self-regulating living environment that responds to changing internal and external conditions. The human equivalent of these ‘smart’ mounds would be buildings that meet all energy, waste management, heating, ventilation and other needs on site.
The research was filmed by the BBC for inclusion in a Sir David Attenborough natural history series screened in 2006.
In 2004, the crocheted artwork above, developed by two EPSRC-funded University of Bristol mathematicians, aroused international media interest.
The crochet was a striking object created by Dr Hinke Osinga and Professor Bernd
Krauskopf to describe the nature of chaotic systems – such as the weather or a turbulent river – defined by what are known as
Lorenz Equations.
After months of staring at computer animations of these surfaces they realised their computations had naturally generated crochet instructions. Dr Osinga, who learnt to crochet at age seven, took up the challenge, and 25,511 stitches and 85 hours later the Lorenz Manifold, the name they called their creation, was born.
The project included research in Namibia to digitally scan the structure of the termite mounds, which the team turned into a precise 3D reconstruction of
EPSRC 1994-2014
In 2004, EPSRC held its first ‘Sandpit’ event, setting the template for similar blue-sky thinking initiatives subsequently adopted by funding agencies around the world.
One of the inaugural Sandpits, Mapping the Underworld (see pages 62-63), brought together academia and industry to look at innovative ways to best detect and manage the UK’s buried infrastructure such as water pipes, sewers and telephone lines.
Research proposals arising from the
Mapping the Underworld Sandpit spawned a major research project, now in its third phase of EPSRC funding. You can find out more about Sandpits in Pioneer 14.
Dr Osinga says: “The computer-generated crochet instructions were remarkable.
Simply by looking at the real-life surface
I would never have designed it the way the computer did. After all those months of trying to create it on screen, it was fascinating to see the surface grow under my own hands.”
But this wasn’t done just for fun. Osinga and
Krauskopf’s work gave much-needed insight into how chaos arises and is organised in systems as diverse as chemical reactions, biological networks and even your kitchen mixer. The Lorenz Manifold is a very helpful tool for understanding and explaining the dynamics of the Lorenz system.
July 9: SanDisk releases the first SD (Secure Digital) card with a capacity of 1 gigabyte, costing about $500
58

In 2004, the Norwegian
Academy of Science and
Letters awarded the Abel
Prize, equivalent to a Nobel
Prize for Mathematics,
Edinburgh, and Isadore
M. Singer, from Massachusetts Institute of Technology.
jointly to Sir Michael Atiyah
FRS, from the University of
Atiyah (pictured) and Singer received the prize for the Atiyah-Singer index theorem – one of the great landmarks of twentieth century mathematics, influencing profoundly many of the most important later developments in topology, differential geometry and quantum field theory.
Professor Atiyah’s Abel Prize Medal citation recognised his ‘outstanding contribution to the advancement of mathematics, as exemplified by his visionary role in the establishment of the Isaac Newton Institute in Cambridge. The institute, which is part funded by EPSRC, is now an internationally recognised centre of mathematics research thanks to Sir Michael’s direction and guidance in its early years.’
In 1990, Professor Atiyah, a Fields Medal recipient in 1966 (see page 79), became the first director of the Isaac Newton Institute, which was set up to meet the need for a
UK national institute in mathematics and theoretical physics. EPSRC continues to support the institute.
Interdisciplinary research is a key criterion in the selection of the Isaac Newton
Institute’s scientific programmes. To date it has brought together 24 Fields Medallists, eight Nobel Prize winners, 16 winners of the Wolf Prize and nine winners of the
Abel Prize.
In 2013, Professor Atiyah, 85, began a new
EPSRC-supported research project, with
Professor Bernd Schroers, into Dynamics in Geometric Models of Matter.
This ambitious and adventurous research draws on many different areas in mathematics and physics; and could pave the way for a radically new mathematical language for elementary particle, nuclear and atomic physics.
In 2004, Roger Orpwood, from the
University of Bath, became Director of the Bath Institute of Medical Engineering
(BIME), an independent charity developing assistive technology for disabled people.
Among EPSRC-funded projects carried out by the institute, Professor Orpwood led an initiative to develop and demonstrate dementia support technologies in a specially designed smart house in Gloucester.
Under Roger Orpwood’s stewardship, over 100,000 of BIME’s innovative products have been sold, including the Wizzybug powered wheelchair for children with conditions such as cerebral palsy, spinal muscular atrophy, spina bifida and muscular dystrophy.
The technology includes smart monitors to help dementia sufferers deal with day-today situations. For example, a smart tap
(pictured) issues a verbal reminder in a familiar voice to a user who has left a bath running, and turns off the flow of water if the bath gets too full.
In 2012, a two-year EPSRC-funded project in collaboration with BIME developed the inTouch computer interface for people with dementia to ‘virtually visit’ relatives and family, reducing social isolation.
In 2004, EPSRC announced that paper research grant proposals were to be phased out by March 2005, as part of a move to further integrate administration systems between research councils.
When paperless proposals came into effect, the Joint Electronic
Submission (Je-S) system allowed four councils, including EPSRC, to provide their communities with electronic research grant services so that grant proposals can be completed and submitted on line.
This paved the way for universal electronic submissions across all seven research councils.
EPSRC 1994-2014
In 2004, Perpetuum, a spin out company from the University of Southampton, was launched to commercialise a new kind of vibration-based energy harvesting technology developed by Professor
Neil White and his team.
The company’s technology uses kinetic energy resulting from vibration to power wireless sensors via microgenerators, and was swiftly adopted by industry.
Perpetuum has since become a global leader in vibration energy harvesting. Applications for its technology range from industrial plant monitoring and transportation to healthcare and aerospace.
In 2013, Perpetuum won the contract to equip all 148 of Southeastern
Railway’s Electrostar train stock, which includes 618 cars and carriages, with sensor systems to monitor the wear of bearings and wheels to help maintenance engineers determine when maintenance is needed.
December 26: A 9.3 magnitude earthquake creates a tsunami, causing devastation in Sri Lanka, India, Indonesia, Thailand, Malaysia and the Maldives
59

2005
EPSRC 1994-2014 February 22: At least six men stage Britain’s biggest robbery ever, stealing £53 million from a Securitas depot in Tonbridge, Kent
60

In 2005, one of the early protagonists of green chemistry, Professor Martyn Poliakoff
(pictured), set up the Driving Innovation in
Chemistry and Engineering (DICE) project at The University of Nottingham, with funding from the first wave of EPSRC’s
£120 million Science and Innovation
Awards scheme (see page 68).
The project, which followed a host of
EPSRC research grants, including a
Clean Technology Fellowship awarded to
Professor Poliakoff in 1994, was one of the first to bring chemists and chemical engineers together, and helped reinforce
The University of Nottingham’s reputation as a global leader in green chemistry – which promotes the design of products and processes that minimise the use and generation of hazardous substances.
Working with long-standing industrial partner, Thomas Swan & Co Ltd, Professor
Poliakoff had already developed a radical new type of chemical reactor, able to do the work of a 1,000-litre reactor in just four litres – and thus requiring much smaller amounts of chemicals to produce the same end product.
The reactor exploits the unusual properties of supercritical fluids (SCFs) which flow like gases but behave more like liquids – making them ‘clean’ solvents suitable for many types of reaction.
In 2007, Professor Poliakoff and DICE member Professor Mike George, working with pharmaceutical multinationals
AstraZeneca and Sanofi, and Thomas
Swan, used their expertise in supercritical fluids to develop a greener approach in the production of a highly reactive form of oxygen, known as singlet oxygen, which has applications in areas such as photosensitised oxidations, and synthesis of reactive compounds. The team showed how green chemistry methods could yield significant reductions in waste during the production process.
The success of this EPSRC-funded project sparked the interest of the Bill and Melinda
Gates Foundation, since the use of singlet oxygen may have a critical role to play in the safer and more effective manufacture of anti-malarial drugs – combatting malaria is central to the foundation’s mission.
“Progress has been very good and the results will be published soon,” Professor
Poliakoff says.
In 2008, a hugely productive EPSRCsupported collaboration between Professor
Poliakoff, who had just been awarded the
CBE, and video journalist, Brady Haran, resulted in a series of short films on each of the 118 elements in the Periodic Table.
It took just five weeks. “It was completely bonkers,” Professor Poliakoff says. “When we had made the films, we thought we had finished, but that was just the start of it.”
By 2010, The Periodic Table of Videos had received nearly 20 million YouTube views in over 200 countries. The key to their popularity is their accessibility, and quirky but knowledgeable approach to their subjects. Professor Poliakoff says: “One morning, I discovered that overnight I had lectured to more people than I had reached in my entire career.”
By 2011, the Nottingham team’s web site boasted 320 videos, with content covering molecules as well as elements and featuring a growing multidisciplinary team of Nottingham colleagues. Today, the site has 537 videos and over 510,000 subscribers with many followers on social media.
In 2011, Professor Poliakoff was elected
Foreign Secretary of the Royal Society, adding to his 2002 Royal Society Fellowship.
The role sees him travelling the world as an ambassador for chemistry and UK science.
In 2012, Professor Poliakoff was awarded the Royal Society of Chemistry’s Nyholm
Prize for Education, largely for his work on
The Periodic Table of Videos.
In April 2014, Professors Poliakoff and
George joined chemical engineer Steve
Pickering and 11 industrial partners in an
EPSRC-funded project to investigate the role that light could play in the manufacture of chemicals. Poliakoff describes the project as a direct legacy of DICE.
Another Poliakoff legacy – though he would never claim it as his – is the building of the GSK Carbon Neutral Laboratory for
Sustainable Chemistry at Nottingham, which had been due for completion in 2015.
Sadly, the building was devastated by a fire in September 2014 but already the university has pledged the facility will be rebuilt. The new laboratory will provide facilities for three new Chairs in
Sustainable Chemistry, funded by GSK,
EPSRC and The University of Nottingham.
GSK has a long-standing strategic relationship with both EPSRC and the university, and the new professors will expand the interdisciplinary approach to green chemistry that Professor Poliakoff started more than 30 years ago.
61
EPSRC 1994-2014 November 30: Surgeons in France carry out the first human face transplant

2005
EPSRC 1994-2014 May 5: The United Kingdom general election takes place, in which the Labour Party is re-elected for a third consecutive term
62

In 2005, EPSRC invested in a major multidisciplinary, multi-university project to prove the concept of technologies that could explore the underworld of buried pipes, cables and utilities beneath our feet.
In the UK it is estimated that up to four million holes are cut into the UK road network each year to install or repair buried infrastructure. Failure to identify accurately the location of existing buried assets results in numerous practical problems, costs and dangers for utility owners, contractors and road users.
The Mapping the Underworld (MTU) project, which arose from a seminal EPSRC
Sandpit exercise (see page 58), focused on developing the means to locate, map in 3D and record the position of all buried utility assets without excavation. This would be achieved through the development of a single shared multi-sensor platform.
To meet the challenge, the team developed vibro-acoustics, low frequency electromagnetic fields, passive magnetic fields and ground penetrating radar technologies, combined with intelligent use of existing utility company records and ground databases.
The project, led by Professor Chris Rogers, from the University of Birmingham, aimed to integrate the sensor and record information in a single, integrated, searchable database.
The research led to the establishment of an industry-sponsored, co-created MTU
Centre of Excellence, which opened up for the first time the possibility of a national certification scheme – something the industry had wished to see for some time.
In 2010, the Mapping the Underworld project spawned a major archaeology project to help scientists discover unknown historical treasures hidden beneath the
UK landscape.
The three-year £815,000 initiative was co-funded by EPSRC and the Arts and Humanities Research Council
(AHRC) under the Science and Heritage programme (see page 92).
In 2011, Oxems, a company created to commercialise research arising from the
MTU project, developed a unique low cost, low maintenance ‘asset tag’, which can be attached to exposed assets such as water pipes, sewers and cabling and detected when reburied by an ‘intelligent’ sensor device on the surface without the need for excavation.
Oxems believes the technology could reduce the costs to utilities of streetworks by at least 40 per cent, and prompted
John Divit, Leakage Best Practice Adviser at Severn Trent Water, to comment: “The
Oxems product could have an impact as significant as barcodes.”
In 2012, EPSRC invested £6.3 million in a multidisciplinary, multi-university research project led by Professor Chris Rogers focused on transforming the engineering of cities to deliver a low-carbon, resourcesecure sustainable future.
The wide-ranging project draws on the social sciences and takes into account factors such as quality of life, social aspirations and engineering policy.
Co-investigators on this project include
University College London’s Professor
Hélène Joffe (see pages 74-75) and
Professor Nick Tyler, also from UCL.
In 2013, EPSRC invested £5.8 million in the next phase of the Mapping the Underworld initiative, Assessing the Underworld (ATU), which broadens the skill base of the MTU team by introducing leaders in climate change, engineering sustainability, robotics and pipeline systems.
A main aim of the four-year project is to prove the concept of a single integrated assessment and modelling framework.
The programme has more than 50 project partners and has attracted over £16 million of in-kind support. The programme’s intention is to realise a 25-year vision for sustainable streetworks.
Also in 2013, Dr Nicole Metje, from the University of Birmingham, who coleads Assessing the Underworld, was awarded £241,000 by EPSRC as part of an Innovate UK-funded project to develop an inexpensive sensor-based pipeline leak detection system, which can be fitted to new water pipelines or retrofitted opportunistically during repairs or using keyhole excavation technology.
The project, which is a collaboration with water companies and other industry stakeholders, aims to develop a commercial system that harnesses the technology.
Chris Rogers says: “This sequence of funding has underpinned radical thinking on how cities should be supported in the far future and how existing infrastructure systems, some of which date back to the
1800s, can be integrated into the brave new world of smart and smarter cities.”
In 2014, EPSRC invested in a Quantum
Technology (QT) Hub (see page 79) at the
University of Birmingham. Dr Nicole Metje, a co-investigator at the hub, will explore the use of QT sensors for pipeline detection, working alongside the MTU sensors.
EPSRC 1994-2014 May 24: North Korea bans mobile phones
63

2005
In 2005, Dr
Adrian Bowyer, an engineering researcher working with the University of Bath’s
EPSRC-funded
Innovative
Design and
Manufacturing
Research
Centre, made a modest application to the centre for £20,000 to build a 3D printer based on reproductive biological principles which, with man’s help, would be capable of replicating itself.
“The sum I asked for was about half the cost of the cheapest 3D printing machine available on the market at the time,” says the recently retired University of Bath engineer. Not only would he try to run the whole project on this modest budget, he set himself “the challenge of turning a machine that costs £40,000 to buy into something that costs £400.”
The result was RepRap, a remarkable DIY
3D printer that achieved all the project’s stated goals.
To achieve this, Dr Bowyer had a secret weapon in the form of engineering doctoral student Ed Sells, who in 2005 came within an ace of winning the national Science,
Engineering and Technology award for the best student project in the country, based on his work with Bowyer on the RepRap project. Ed Sells was to prove key to the development of the technology, and is now a senior research figure in one of the world’s leading 3D printing companies,
3D Systems.
For Dr Bowyer, the key to success was making the project open source – a free licence to the product’s design or blueprint, enabling subsequent improvements to it by anyone, anywhere.
By 2007, Bowyer and Sells had established a global ‘virtual’ team of over 30 volunteer collaborators, from software developers to designers and mechanical engineers.
Adrian Bowyer says: “The group were
EPSRC 1994-2014 November 30: John Sentamu becomes the first black archbishop in the Church of England with his enthronement as the 97th Archbishop of York
64

unimaginably helpful, and gave us a lot of bang for our buck.”
By May 2008, within a few minutes of being assembled, the first ‘child’ RepRap machine had built the first component for a ‘grandchild’. Dr Bowyer estimates that by
September 2008 over 100 copies had been produced around the world.
In 2009, three RepRap volunteers from
New York, Zach Smith, Bre Pettis and Adam
Mayer, used the knowledge from the project to set up their own company, MakerBot.
“They didn’t have a bean between them,” says Dr Bowyer who, “being horribly old”, did have a few beans to rub together and helped them with $25,000 dollars to form the start-up – and so, MakerBot was born. Within four years, the company had captured 20 per cent of the multi-million dollar US market in home-use 3D printers.
In August 2010, Dr Ed Sells left Bowyer to join UK start-up Bits from Bytes, which, using modified RepRap technology, had gone from launch in January to a £2 million business by the end of the financial year.
In 2011, open source hardware company,
Aleph Objects, based in Colorado, established LulzBot to make 3D printers, parts and materials which, Aleph says, are “all developed as part of the RepRap project”. The company now has 540 employees, and exports worldwide.
In the same year, MakerBot raised a further
$10 million from the likes of Facebook’s
Sam Lessin and Amazon CEO, Jeff Bezos.
In October 2011, rising bioengineering star, Jordan Miller, of the University of
Pennsylvania, and a core member of the
RepRap project, used a RepRap Mendel and a Makerbot 3D printer to make blood vessels from sugar. His method later appeared in a special edition of Scientific
American on the future of medicine.
By 2012, MakerBot had generated annual income in excess of US$11 million and was selling more than 20,000 printers a year
– including the MakerBot Replicator 2 – inspired by RepRap.
In June 2013, one of the world’s largest
3D printing companies, Stratasys, made an offer MakerBot could not refuse. The company Adrian Bowyer helped create for
$25,000 four years earlier was sold for the sum of $403 million, with an additional
$200 million in potential performancebased bonuses.
Dr Bowyer says he knew from the outset that RepRap had the potential to grow exponentially; but even he could not have predicted how an idea that began with a
£20,000 EPSRC grant could have developed so fast, in so many countries, and evolved in so many diverse ways – with no sign of slowing down.
Designed to ‘laser print’ products layer by layer, with virtually zero waste, additive manufacturing (AM), otherwise known as 3D printing, has the potential to revolutionise the way we make things. But there are still significant hurdles to overcome before successful commercialisation of the technologies.
EPSRC-supported research groups across the UK are developing worldleading technologies and processes at the forefront of this research.
In addition to individual AM projects,
EPSRC-supported research groups include the £4.5 million EPSRC Centre for Doctoral Training in Additive
Manufacturing and the EPSRC Centre for Innovative Manufacturing (CIM) in
Additive Manufacturing, hosted by the
University of Nottingham in partnership with Loughborough University.
CIM projects include development of ways to deposit more than one material within a single build process, making it possible to print entire working systems
(incorporating electronics, for example) in one go, instead of making individual parts or components – taking AM to the next technological level.
Main picture: It’s a rap: Dr
Adrian Bowyer (left) and Vik
Oliver, a member of the RepRap project, proudly show off a new addition to the family. All of the plastic parts for the machine on the right were produced by the almost identical machine on the left.
Top left: the original
RepRap 1.0 ‘Darwin’ prototype.
EPSRC 1994-2014 December 11: The Buncefield Oil Depot in Hemel Hempstead, England, is rocked by explosions, causing a huge oil fire
65

2005
In 2005, Dr Chris Solomon and Dr Stuart
Gibson, two physicists from the University of Kent, created their first version of an
‘electronic sketch artist’ that has changed the way UK police forces identify criminals.
Their system, EFIT-V, allows victims and witnesses to select the best and worst matches from a group of computergenerated faces, helping identify suspected criminals in a new way.
Based on the witnesses’ responses, the computer system eventually ‘learns’ what type of face they are after and displays options accordingly.
Dr Solomon’s EPSRC-supported research led directly to the creation of spin out company VisionMetric Ltd. Fast forward to
2014 and VisionMetric’s facial composite products, EFIT-V and E-FIT, have become the preferred choice of 90 per cent of
British police forces and are used in over
30 countries around the world.
Computerised facial composite systems in the UK date back to the late 1980s and the original E-FIT system – which was developed by John Platten, a software engineer, and Peter Bennett, a former
Metropolitan Police officer.
Dr Solomon says: “E-FIT has developed a reputation as a highly reliable and flexible system for feature-based composite construction. However, it relies on the witness’s ability to recall individual features, provide verbal descriptions and then select them from stored libraries of labelled features. This is a task which extensive psychological research shows that witnesses often find difficult. Through our early research in computer vision we began to suspect that a better approach could be taken.
“The EFIT-V facial composite system is based on different principles, employing a holistic (whole face) approach to construction. In essence, the witness is shown a number of randomly generated faces and is asked to select the one that best resembles the target. A genetic algorithm is then used to breed a new generation of faces based upon the selected individual. This process is repeated until the user is satisfied with the composite generated.”
Today, EFIT-V has evolved into what is widely accepted to be the most advanced facial composite software, enabling the creation of near photo-realistic, colour images of criminal suspects from eyewitnesses’ testimony and is credited with helping to solve hundreds of crimes.
Dr Stuart Gibson says: “The key advantage with EFIT-V is that the technology allows people to respond to faces they see rather than having to break it down into component parts.
“Police forces using EFIT-V have reported sustained, correct naming rates up to
10 times the average success rate using feature-based systems.
“EFIT-V is even effective when witnesses cannot provide good descriptions of the face but know that they would recognise the face if they saw it again.”
EFIT-V is now in use globally, and has customers from as far apart as Europe,
Australia, USA, Singapore and Chile.
Among excellent customer reviews, a satisfied client from New Scotland Yard wrote: “I thought it would be appropriate to let you know as soon as possible about the new product. Put simply, I love it… This has led to six cases so far getting ‘near as damn-it’ likenesses.”
Spot the fakers: Only one of the pictures above is a real photograph; the others were created by EFIT-V.
EPSRC 1994-2014 August 29: Hurricane Katrina makes landfall along the US Gulf Coast, causing severe damage. At least 1,836 die in the aftermath
66

In 2005, an EPSRCsupported team from the universities of Dundee and
St Andrews, led by Dr
Norman Alm, developed a simple touch-screen aid to help dementia sufferers recall their memories.
The aid was simple to use and stimulated more enjoyable, rewarding conversation between sufferers and those who care for them.
During development, the
CIRCA system was tested on
40 dementia sufferers in day care, nursing home and family situations, with many carers reporting that sufferers seemed like their old selves.
CIRCA exploits the fact that, while dementia sufferers find it hard to recall recent events, longer-term memory is less affected by their condition.
The team secured further EPSRC funding from the EPSRC-led RCUK Digital Economy programme to develop an interactive multimedia activity system that dementia sufferers can use on their own.
In 2005, EPSRC launched its Challenging
Engineering Awards programme, through which support is given to the most promising early career researchers.
The highly successful programme was designed to identify and support individuals with the potential to become future leaders of engineering research, with the ambition of building a team around them over the course of a five-year period to achieve their research vision.
In total, £35 million in Challenging
Engineering Awards was invested in nearly 40 researchers in areas
EPSRC 1994-2014
CIRCA team member Dr Arlene Astell, of the University of St Andrews School of
Psychology, says: “Dementia sufferers’ declining ability to hold normal conversations causes a lot of stress and frustration.
“Helping them access their memories makes living with dementia more bearable and less distressing for sufferers and their carers.”
The research led to the formation of Circa
Connect Ltd, a spin out company, which brings together expertise in the fields of design, psychology and computer science to commercialise the work.
such as materials, mechanical and medical engineering, information & communications technologies and process, environment & sustainability.
In 2011, many of the features of the programme were incorporated into
EPSRC’s new Fellowship framework.
In December 2005, EPSRC held its first
Council Open Forum. The event, held at the Royal Institution, opened the floor to anyone wishing to put questions to members of EPSRC’s Council, its seniordecision-making body. Open forums have since been integrated into EPSRC’s ongoing programme of engagement with the research community.
April 27: The Superjumbo jet aircraft Airbus A380 makes its first flight from Toulouse, France
In 2005, Dr Julie Macpherson, an EPSRCfunded researcher from the University of
Warwick, won the influential Times Higher
Education magazine’s inaugural award for
Young Researcher of the Year.
She received the award in recognition of pioneering research into single-walled carbon nanotubes, which made it possible to map the chemistry of surfaces at a molecular level, with potential applications in areas such as cell signalling processes and the detection of aircraft corrosion.
Professor Macpherson is also recognised for her research into the development of new synthetic diamond electrochemical sensing devices and techniques.
She co-leads the Warwick Electrochemistry and Interfaces Group, and is Taught Course
Leader at the EPSRC Centre for Doctoral
Training in Diamond Science and Technology.
The centre is working with companies such as De Beers Group and synthetic diamond specialist Element Six to help pioneer new diamond-enabled technologies.
Professor Macpherson says: “Interfacing with and integrating diamond into electronic devices can solve some of the biggest research problems, such as effective cooling for faster and more reliable devices; and lasers that are more powerful and compact than current devices.”
In May 2014, Professor Macpherson was awarded a four-year Royal Society Industry
Fellowship in acknowledgement of her work in diamond electrochemistry.
The fellowship will enable Professor
Macpherson and her team to push forward the significant work already accomplished with Element Six.
67

2005
In 2005, EPSRC launched its Science and Innovation Awards programme, a major tranche of funding focused on directly building the UK’s research base through large-value, long-term grants in strategically important research areas identified as being missing or ‘at-risk’ in the UK.
Funded by EPSRC in partnership with the Higher Education Funding Council for England (HEFCE) and the Scottish
Higher Education Funding Council, the projects, awarded annually for five years, created centres of excellence in their respective fields under the leadership of a principal professor. The scheme supported
29 programmes of research activity with a value in excess of £120 million.
The diversity of the research activity is testament to the scope of the investment, with new centres of excellence emerging in areas such as intelligent software; graphene and its applications in nanoelectronics, photonics and bio-sciences; synthetic biology and innovation; carbon capture related to fossil fuels; energy efficient cities; statistics underpinning science, technology and industry; and green chemistry.
Among recipients of a
Science and Innovation
Award were Professor
Martyn Poliakoff, from The
University of Nottingham
(see pages 62-63) and
Professor Lynne Gladden from the University of
Cambridge (see page 70).
Hands-on research: Asieh Kazemi, a researcher from the
University of Bath’s Centre for Graphene Science, operates the
‘nano-factory’, which will allow researchers to build new devices onto a single graphene layer. The centre has been funded by strategic investments by the universities of Bath and Exeter into materials research, and by a £5 million award from the EPSRC/
HEFCE Science and Innovation Awards programme in 2008.
Photograph courtesy: SWNS.com
In 2005, a team of aerospace engineers at the University of Bristol, led by Dr
Ian Bond, developed a revolutionary new technique that could enable damaged aircraft to mend themselves automatically, even during a flight.
If a tiny hole or crack appears in the aircraft – due to fatigue or a stone strike
– epoxy resin ‘bleeds’ from embedded vessels near the crack to quickly seal it and restore integrity. The resin and hardener enable the composite material to recover up to 80-90 per cent of its original strength, comfortably allowing a plane to function at its normal operational load.
In addition to improving aviation safety, the technology, which mimics the healing processes found in nature, could also lead to lighter aircraft, cutting both fuel costs and carbon emissions.
In 2008, EPSRC awarded Professor
Bond a further grant to continue the development of these techniques.
Today, Professor Bond co-leads the
EPSRC Centre for Doctoral Training in
Advanced Composites for Innovation and
Science at the University of Bristol.
68
EPSRC 1994-2014 September 12: Israel completes its withdrawal of all troops and settlers from the Gaza Strip

In 2005, a team from the School of Ocean and Earth Science (SOES) at the University of Southampton used EPSRC funding to create a device that could identify undersea objects such as shipwrecks, mines and piping, even if they are buried in sand or mud.
The team, led by Professor Jonathan Bull, developed the first truly three-dimensional sub-seabed profiler called GeoChirp 3D, which they successfully demonstrated by imaging the skeleton of The Invincible, a
Royal Navy ship that sunk into the Solent sands in 1758.
Developed with the help of GeoAcoustics
Ltd, a manufacturer of sonar seabed survey equipment, the GeoChirp 3D is a surface-towed seismic system that works by firing sound waves at the sea floor and measuring the reflections as they bounce back from objects and different rock layers beneath the seabed. The concept came from the petroleum industry, which uses seismic reflections to locate oil and gas fields.
The system, which later went into production, is capable of imaging the upper tens of metres of the sub-surface in three dimensions and provides the perfect base for shallow-water engineering, archaeology, military and geological studies.
GeoChirp has been successfully used during surveys in near-shore and harbour environments in the UK and internationally.
Development of the GeoChirp system was funded by GeoAcoustics Ltd, EPSRC and
English Heritage.
EPSRC 1994-2014
In 2005, an EPSRC-supported team of specialists in fire chemistry, polymers and textiles, led by Dr Baljinder Kandola at the
University of Bolton, developed a range of new, inherently flameretardant polymers.
The breakthrough was a result of a 2003 project funded by EPSRC and the MoD to investigate the use of nano composites in synthetic materials. The multidisciplinary, multi-university team’s research was based around the belief that the barrier layer and char-forming properties of nano composites could improve fire resistance of synthetic fibres, while enhancing their physical and mechanical properties.
The team later turned their attentions to creating a new generation of textiles with applications ranging from soft furnishings to soldiers’ uniforms.
Today, Dr Kandola is a member of the FRBiocomp group at the
University of Bolton, funded by
Innovate UK, which aims to develop fire-retardant, environmentally sustainable composites using natural fibres and biopolymers.
In 2005, a research team at the universities of Sheffield and Liverpool, led by Dr Steve
Millard, began development of a new type of concrete that could help protect terrorist targets against car or lorry bomb attacks.
The team’s Ultra High Performance Fibre
Reinforced Concrete (UHPFRC) has needlethin steel fibres added to the concrete mix instead of or in addition to steel reinforcing bars to increase its tensile strength.
Developed over four years, in partnership with the Centre for the Protection of
National Infrastructure, UHPFRC was found to absorb a thousand times more energy than plain concrete and could therefore be used for bomb-proof litter bins and protection barriers.
The concrete has been utilised in Australia in the design of slender footbridges and other specialised applications.
November 27: The first partial human face transplant is completed in Amiens, France
69

2006
In 2006, building on previous EPSRC investments, the international Silent
Aircraft Initiative (SAI), a collaborative venture between the University of Cambridge and
Massachusetts Institute of Technology
(MIT), unveiled its revolutionary single-wing concept SAX-40 aircraft (pictured above).
The highly-efficient design, which has neither flaps nor slats (a major source of aircraft noise), offered improvements of around 25 per cent in the fuel consumed in a typical flight compared to current aircraft and offered significant noise reductions compared to conventional aeroplanes.
The academic/industry project, supported by EPSRC and the Cambridge-MIT Institute, focused on next-generation aeroplanes entering into service in 2030 and was led by Cambridge’s Professor Ann Dowling
(pictured), a world authority on combustion and acoustics. Commercial partners of this multi-partner initiative included BA, Rolls-
Royce and the Civil Aviation Authority.
Interviewed in 2006, Jim Morris, Vice
President of Engineering & Manufacturing at Boeing Commercial Airplanes, said:
EPSRC 1994-2014
“This collaboration has stretched our imagination and generated noise mitigation ideas that we will be able to study for potential future use.”
Colin Smith, Rolls-Royce Director of
Engineering and Technology, said: “The study confirmed that the solution for extremely low noise must be a highly integrated combination of engine and aircraft design and operation.”
In 2007, the Silent Aircraft Initiative led to a four-year EPSRC-supported project, jointly with MIT, investigating the development of embedded engines mounted above the wing to reduce noise on the ground and increase the aircraft’s efficiency.
In 2008, Professor Dowling co-led a major
EPSRC-funded project into energy efficient cities, led by Professor Lynne Gladden at the University of Cambridge. The findings of this project, funded by an EPSRC Science and Innovation Award (see page 68), influenced future government policy.
In 2009, Professor Dame Ann Dowling, who received a DBE for services to science in
2007, became head of the Department of
Engineering at the University of Cambridge.
In 2011, EPSRC funded a four-year project jointly with Caltech focused on reducing the environmental impact of take-off noise from aircraft.
The work, co-led by Professor Dowling, merges with and extends two highly successful earlier EPSRC-funded jet noise projects, specifically looking at aerodynamics and aero-acoustics of complex geometry hot jets and the dynamics of co-flowing jets.
In 2014, Professor Dowling co-leads the new EPSRC Centre for Doctoral Training in
Gas Turbine Aerodynamics at Cambridge.
In 2014, EPSRC invested over £10 million in a new National Wind Tunnel Facility.
The investment, which includes £2.6 million from research partner the UK
Aerodynamics Centre, will finance seven wind tunnels at universities throughout the UK.
Professor Dame Ann Dowling, who in
2013 became Chair of the UK Aerodynamics
Council, says: “The new wind tunnel facility will give researchers and industry access to the world-class facilities and instrumentation vital for the development of future quiet, ultra-efficient aircraft.”
In 2014, Dame Ann was appointed
President of the Royal Academy of
Engineering, the first woman in the role.
July 28: The Provisional IRA issues a statement formally ordering an end to the armed campaign it has pursued since 1969
70

In 2006, an EPSRC-funded project led by Professor Lynne Macaskie at the
University of Birmingham demonstrated the commercial potential arising from ‘feeding’ a certain type of bacteria on high-sugar waste products, such as those produced by the confectionery industry.
The bacteria give off hydrogen as they consume the waste, and the team used this gas to generate clean electricity via a fuel cell – potentially a valuable source of non-polluting energy in the years ahead. The waste was supplied by the team’s industrial partner, Cadbury Schweppes plc, whose factory is conveniently located just down the road. The waste would otherwise have been sent to landfill.
Since 2006, Professor Macaskie has headed several EPSRC-supported projects to evaluate the potential for using bacteria to bio-manufacture precious metal catalysts.
Precious metals, such as platinum and palladium, are used extensively in a wide range of industrial chemical processes – providing a vital trigger or accelerator for chemical reactions. A current EPSRC-project, of which she is a member, is applying novel bionano-catalysts for upgrading heavy oils.
In 2006, a sister project to the sugarrelated research, led by the Biotechnology and Biological Sciences Research Council
(BBSRC), evaluated the potential for sourcing precious metals from wastes: together these projects have demonstrated a ‘one stop shop’ method to bio-manufacture active catalysts from waste.
The combined research projects spawned a life of their own through a pioneering commercial venture launched by Dr Angela
Murray (pictured), a bioscientist at The
University of Birmingham.
In 2009, Dr Murray, whose doctorate was supervised by Professor Macaskie, used a BBSRC Enterprise Fellowship Award to develop a way to recover precious metals from roadside waste, with the aim of producing new, cheap catalysts. This led to the creation of a spin out company,
Roads to Riches. Macaskie and Murray are both directors of the company, which works closely with the Birmingham research teams.
The catalytic converters in most modern cars are coated with precious metals, including palladium, rhodium and platinum.
Over time, tiny particles of these metals are ejected through the exhaust system, settling as highly valuable road dust. Rhodium, for example, sells for around £100 a gram.
All UK councils are required by law to clean up and collect road waste, so this part of Roads to Riches’ operation is free.
Next, the company uses natural separation techniques, such as magnetism, to sort out the metals from the organic road waste, which is processed into low grade building aggregates, rather than sent to landfill.
What’s left is a metal concentrate, which traditionally would be sent for energyintensive smelting. The company has developed a greener option – it sends in the bacteria.
The bacteria used in the process are already on their second life, having been used in the earlier process to create clean hydrogen from fermented food waste.
After being added to the metal concentrate, the bacteria emerge wearing what Angela
Murray has described as “tiny nanoparticle metal jackets”.
The bacteria are then either dried into a fine powder to make a range of platform chemicals/catalysts or can be used in hydrogen fuel cells to generate clean electricity. In essence, the bacteria producing the hydrogen are the same ones recovering the precious metals.
In 2006, Syrinix, a company formed in 2004 by Professor Paul Linford to commercialise his EPSRC-funded blue-skies research at the University of East Anglia, was named
Business Initiative of the Year in the Times
Higher Education Supplement 2006 awards.
The company’s awardwinning portfolio has developed
‘listening’ technology that can help reduce the
3.3 billion litres of treated water lost every day in the UK by making maintenance more cost effective.
The technology uses vibro-acoustic signals from the water mains pipe and analyses these sounds to enable leaks to be detected in their early stages and pinpoint their location.
Detection stops bigger, more devastating leaks from springing up and helps water companies prevent massive loss of water
EPSRC 1994-2014 April 23: YouTube, the popular video sharing website, is founded and damage to roads and buildings surrounding the pipes.
In 2013, Syrinix’s TrunkMinder technology was short-listed for the Most Innovative
New Technology of the Year title at the
Water Industry Achievement Awards.
Also in 2013, the company secured
£2.1 million in funding from a number of investors, including the EU-funded
Low Carbon Innovation Fund, and the
Angel CoFund, to accelerate national and international growth.
Today, the company’s TrunkMinder devices are being commercially deployed in a major rollout by Thames Water for the £15 billion Crossrail project, one of the largest engineering projects in Europe.
To avoid catastrophic pipeline failures,
Syrinix worked closely with Crossrail to deploy the system on critical water mains, many of which have been in the ground for decades and some for in excess of
100 years.
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2006
In 2006, Tissue Regenix, a medical devices company in the field of regenerative medicine specialising in human tissue regeneration products, was founded by
Professors John Fisher and Eileen Ingham to commercialise their EPSRC-funded research at the University of Leeds.
The company’s proprietary dCELL ® technology platform works by removing all cells from the animal tissue, allowing it to be used to replace worn out or diseased body parts – without the need for antirejection drugs.
Because a patient’s own cells can populate the new biological scaffolds, they are accepted by the immune system and can be repaired like normal tissue. The dCELL ® process can be used to make 20-30
different products.
Potential applications for the technology, which has been licensed for use in tissue banks in the UK and South America, include knee damage repair, heart valves and advanced wound care for leg ulcers.
In 2010, Tissue Regenix’s first product – a vascular patch derived from pig tissue which repairs damaged human veins – gained its CE mark and was sold globally outside the USA.
In 2012, the company, now listed on the
London Stock Exchange’s international market for smaller growing companies
(AIM), opened an office in the USA as a significant step forward in its commercialisation strategy.
Today, the Tissue Regenix Group has a market capitalisation of over £60 million. The basic research that led to the company’s formation was funded by EPSRC in 2000, and Tissue Regenix continues to receive EPSRC support.
Professor Eileen Ingham says: “The support from EPSRC and other funders, including the Technology Strategy Board, over many years has been crucial in enabling us to pursue the basic technology and then drive forward its potential. We were able to use these grants flexibly, enabling continuity of employment for key researchers.”
EPSRC 1994-2014
In 2006, a laboratory designed to make pedestrian environments safer and easier to use was set up with EPSRC support at University College London (UCL). The investment stemmed from a three-year
EPSRC grant awarded to UCL’s Accessibility
Research Group to create a new lab for investigating issues related to pedestrians and the pedestrian environment.
The PAMELA (Pedestrian Accessibility and Movement Laboratory) project, led by Professor Nick Tyler, led to the development of a ‘lab-based’ fullyconfigurable pedestrian walkway, enabling real-world conditions to be replicated in a controlled setting.
May 1: The Human Genome Project publishes the last chromosome sequence
By monitoring and measuring all aspects of pedestrian behaviour – from their gait and biomechanics to how they perceive the world around them – the project has generated data leading to improvements in the design of pavements, footways and concourses, and will enable new ideas and products to be tried out.
Today, among other EPSRC-supported projects, Professor Tyler, who has received over 20 EPSRC research grants, is a key member of the Transforming the
Engineering of Cities project (see pages
62-63), and co-leads a team investigating the feasibility of a wholly new concept in exoskeleton design.
72

In 2006, Magnomatics, a high technology company from the
University of Sheffield, was set up to commercialise groundbreaking research by Dr Kais
Atallah and Professor David
Howe into magnetic transmission systems, high-torque electrical machines and electromechanical actuators and dampers.
The inspiration to form the company came from an EPSRCsupported project to investigate the advantages of magnetic gears over their mechanical counterparts for a range of applications.
Members of Dr Atallah’s original research group formed the core of the Magnomatics technical team.
In 2012, the company, now active in a range of industries, including renewable energy, automotive, aerospace and defence, secured funding of
£2.5 million to complete the development of its magnetically-geared motors for the electric and hybrid vehicle market.
Today, Magnomatics has evolved into a clean technology company employing over 30 people, with a strong focus on renewable energy and energy efficiency.
Together with its various strategic partners, the company is developing a range of technologies, including high efficiency, ultra-compact generators for wind and tidal energy production; ultracompact and efficient marine propulsion systems; and wheel hub motors and continuously variable transmissions to be employed in commercial hybrid and electric vehicles.
In 2006, Warwick Warp, a spin out company from the University of Warwick, won the
Research Councils UK Business Plan
Competition for its unique software-based fingerprint identification system.
Warwick Warp’s technology, which was substantially more reliable and faster than those available at the time, can be incorporated into identity cards and
EPSRC 1994-2014 biometric passports – and so could be used to help combat crimes such as identity theft, social security fraud, people trafficking and terrorism.
In 2009, the system, which can identify partial, distorted, scratched, smudged, or otherwise warped fingerprints in just a few seconds, scored top marks in the world’s two toughest technical fingerprint tests.
It was ranked best for overall accuracy by the UK National Physical Laboratory and placed third overall out of 36 in tests by the US National Institute of Standards and
Technology (NIST).
In 2013, the company’s fingerprint feature extractor was certified for use in
India, where the Warwick Warp is being deployed in multiple government and civilian projects.
In 2007, EPSRC set up a new advisory panel to advise Council, its senior decision-making body, about how best to take account of public opinion and attitudes in policy development.
The Societal Issues Panel (SIP) complemented the Technical
Opportunities Panel (TOP), which mainly comprised academics, and the User
Panel (UP), whose main component is industrialists.
In 2011, EPSRC’s panel system, which had remained largely unchanged for nearly two decades, evolved into a more flexible Strategic Advisory
Network (SAN).
March 21: Jack Dorsey, Noah Glass, Biz Stone, and Evan Williams found social networking service Twitter, officially launched later in 2006
73

2007
In 2007, structural earthquake engineer,
Professor Tiziana Rossetto, received an
EPSRC Challenging Engineering award to establish the Earthquake and People
Interaction Centre (EPICentre), based at
University College London (UCL). She is also director of the centre.
It was Professor Rossetto’s experience of surveying the sites of the 2004 earthquakes and tsunami in Sri Lanka and Thailand with the UK’s Earthquake Field Investigation
Team (EEFIT) that led her to set up a multidisciplinary research group under
EPSRC’s Challenging Engineering scheme.
Launched in 2005, the scheme identified and supported individuals with the potential to become future leaders of engineering research, with the ambition of building a team around them (see page 67).
The EPICentre team of earthquake engineers, social scientists, psychologists, coastal engineers and statisticians investigate and model risk from natural hazards to buildings and infrastructure and study their impact on populations. The team study disasters in the field, and their research covers earthquakes, tsunami, volcanoes, floods, risk reduction and risk representation.
In 2009, with EPSRC support, EPICentre unveiled a unique wave-generation facility which can accurately model realistic tsunami waves. Developed by EPICentre and marine engineering specialists,
HR Wallingford, the tsunami generator has a 70-metre long, four metre-wide flume, and includes a coastal slope and model beach to show how the coast, buildings and structures are affected.
Professor Rossetto says: “The main gap in our knowledge is about what happens when the tsunami wave approaches the near shore region and then runs inland.
“These flow processes cannot be simplified using mathematical models because of the complex interaction that takes place with beaches, sediment, coastal defences and then in and around buildings.”
The tsunami generator has been made available for use by researchers from all over the world.
An example of a project that will use the tsunami generator is CRUST, funded in 2014 by EPSRC to develop a new assessment methodology to help risk management after earthquakes and tsunami.
The CRUST team brings together expertise from the University of Bristol and UCL, and partners widely with industry and universities worldwide.
In 2010, with support from EPSRC,
EPICentre launched the Virtual Disaster
Viewer (VDV), an innovative web-based portal that allows earthquake experts to pool knowledge quickly and effectively to help relief operations.
The VDV captures before-and-after satellite images, videos, and real-time field data, enabling engineers and scientists to provide detailed damage assessments to help relief organisations target emergency supplies, prioritise repairs and plan reconstruction.
The viewer was used in post-earthquake field investigations in China in 2008, Italy in
2009 and after the 2010 Haiti earthquake which killed an estimated 100,000 people.
In 2011, EPSRC funded a five-year project led by Newcastle University to enable
UK scientists to visit an earthquake zone together with the EEFIT team in order to gather data immediately after an earthquake has struck.
Researchers, including those from
EPICentre, used the funding to visit the site of the Tohoku earthquake and tsunami in Japan and the area devastated by earthquake in Christchurch, New Zealand, both in 2011.
In 2012, Professor Rossetto led the firstever earthquake return reconnaissance mission to investigate building repair, strengthening and reconstruction after the
2009 L’Aquila earthquake in Italy. Before the grant ends in 2016, the team will have conducted five investigations in total.
In 2013, EPICentre co-director Professor
Hélène Joffe won the prestigious Lloyds
Science of Risk award for her study of people living in highly seismic areas.
Professor Joffe is a co-investigator in a major multi-university EPSRC-funded project led by Professor Chris Rogers from the University of Birmingham into sustainable future cities (see pages 62-63).
In 2013, EPSRC invested in a £1.6 million
EPICentre project on earthquake and fire risk. The team are developing tools for damage evaluation in fire engineering and are planning an innovative study in Seattle,
USA to get people to prepare and plan for the effects of earthquake and fire.
This research builds on knowledge of risk representation gained in the course of
Professor Joffe’s work.
74
EPSRC 1994-2014 January 9: Apple CEO, the late Steve Jobs, announces the launch of the first iPhone

EPSRC 1994-2014 May 21: Cutty Sark, the last surviving tea clipper, is badly damaged by fire in Greenwich, England
Pictures in descending order:
Professor Tiziana Rossetto talks with locals from Khao Lak, Thailand, as part of an EEFIT mission after the Indian Ocean earthquake and tsunami.
The Fast Flow facility at HR Wallingford, site of the world’s first tsunami generator.
EPICentre team members visited the site of the devastating 2011 tsunami in Tohuku,
Japan, capturing these dramatic images.
75

2007
In 2007, XenSource, a company formed by four EPSRC-supported researchers at the University of Cambridge’s Computer
Laboratory, was sold to US company Citrix for $500 million.
XenSource was set up in 2004 to help commercialise the team’s ground-breaking software, called Xen, which makes a single computer appear to be many similar, but smaller, computers.
Among its key features, Xen enables several people to use the same computer server without being able to affect each other’s personal virtual machine – and without being aware of each other. Each virtual machine can run any operating system and any application.
The notion of getting the most out of the least number of servers initially attracted companies that handled large amounts of data, such as Wall Street banks, which traditionally had hundreds of thousands of servers.
XenSource began as a consultancy service advising banks and other businesses on deploying Xen.
The company’s creators soon realised there were further business opportunities in building and supporting an ‘enterpriseready’ version of Xen, and their work became instrumental in the development of cloud computing through which companies undertake large computing jobs. Amazon was also an early adopter, and used
Xen software in one of the largest cloud computing bases.
Researchers around the world have used Xen to develop further research and generate new applications. Cloud computing has become ubiquitous for both the corporate world and for individual consumers.
Today, Citrix offers a suite of security software including mobile applications for iOS, Android and Windows smartphones and tablets.
EPSRC 1994-2014 June 27: Gordon Brown becomes Prime Minister of the United Kingdom
76

In 2007, EPSRC launched a major initiative for academics to develop the commercial potential of their research alongside commercial businesses in university-based centres of excellence known as Innovation and Knowledge Centres (IKCs).
Successful projects have developed new coatings and surfaces that can be used to turn buildings into power stations; enhanced jet engine efficiency; technologies to help the body heal itself, and systems to combat the threat of cyber attacks and terrorism.
Originally funded by EPSRC, and now cofunded with Innovate UK, with additional funding from the Biotechnology and
Biological Sciences Research Council
(BBSRC), IKCs were set up to accelerate and promote business exploitation of an emerging research and technology field.
The seven centres funded to date have developed ground-breaking work in areas such as manufacturing technologies for photonics and electronics; regenerative medical therapies and devices; and secure information technologies. They have quickly established both a global profile and an international reputation.
Spin out and spin in activity is integral to the IKC concept. Successful companies include Microsense, formed to commercialise research at the Centre for
Secure Information Technologies (CSIT)
IKC at Queen’s University Belfast (see page
81). The company’s award-winning wireless microwave fence was designed for use in critical installations such as airports, power plants and country borders, creating an invisible but sensitive detection curtain around a secure location. It is also able to distinguish between real targets and nuisance environmental disturbances.
The brief is simple: to ensure great ideas are swiftly translated into industrial development, products and jobs. In turn, the techniques and technologies developed are fed back into the research ecosystem.
IKCs have also developed successful partnerships with the Innovate UK-funded
Catapult centres – a network of businessled technology innovation centres designed to advance innovation in specific fields and to enable business to access the best research and technical expertise, infrastructure and equipment.
Operating at an earlier stage than
Catapult centres, IKCs are led by an expert entrepreneurial team and offer a shared space and entrepreneurial environment in which researchers can work side by side with potential customers and professionals from academia and business.
Since 2007, IKCs have created 801 jobs, spawned 11 new spin out companies; filed
60 patent applications; initiated
12 licensing deals and brought 60 products and services to market. They have also trained 273 doctoral students and
213 MSc students.
The IKC concept has gone down well with industry, attracting £132 million in additional research income and
£43 million in business investment through over 180 partner companies and
340 collaborating businesses.
You can find more about Innovation and
Knowledge Centres in Pioneer 13, available to download from epsrc.ac.uk.
77
EPSRC 1994-2014 July 1: Smoking in England is banned in all public indoor spaces

2007
In 2007, an EPSRC-funded team of researchers at the University of Leeds showed that a species of beetle that squirts its predators with a high-pressure spray of boiling liquid could provide the key to significant improvements in aircraft engine design. Their research also inspired work to develop new types of nebuliser, needle-free injections, fire extinguishers and powerful fuel injection systems.
The bombardier beetle squirts its fiery potion, which reaches 100 degrees Celsius, at 300 explosive pulses per second.
The team, led by Professor Andy McIntosh, believed the beetle’s jet-based defence mechanism could help solve a problem that can occasionally occur to jet aircraft at high altitude – re-igniting a gas turbine engine which has cut out, when the outside air temperature is as low as minus
50 degrees Celsius.
The spray’s chemical and physical characteristics and the insect’s physiology were simulated using a scaled-up experimental rig in Professor McIntosh’s lab.
The research, funded initially by EPSRC and subsequently by Swedish Biomimetics
3000 ® , led to the development of new technology, µMist™, which has the potential to become the platform for the next generation of eco-friendly mist carrier systems used in applications such as fuel injection, medical drug delivery systems and fire suppression.
Interviewed in 2007, Professor McIntosh likened the beetle’s defence mechanism to a pressure cooker controlled by a complicated system of valves, saying:
“Essentially it’s a high-force steam cavitation explosion. Using a chamber less than one millimetre long, this amazing creature has the ability to change the rapidity of what comes out, its direction and its consistency.
“Nobody had studied the beetle from a physics and engineering perspective as we did – and we didn’t appreciate how much we would learn from it.”
In 2010, the Leeds team won the prestigious Times Higher Education
Outstanding Contribution to Innovation and Technology Award, in recognition of their breakthrough in the discipline of biomimetics.
In 2013, Swedish Biomimetics 3000 ® , which has a worldwide exclusive licensing agreement with the University of Leeds for the µMist™ platform technology, formed a technical partnership with motorsport engineering specialists Cosworth to advance fuel injection systems inspired by the bombardier beetle’s defence mechanism.
July 21: The final book in JK Rowling’s Harry Potter series, Harry Potter and the Deathly Hallows, is released selling over 11 million copies in the first 24 hours
78
EPSRC 1994-2014

In 2007, a consortium of five university research teams, led by Dr Paul Riley, from
The University of Nottingham, received
£1.6 million in EPSRC funding for a fiveyear project to develop a low cost, high-tech generator that could transform the lives of some of the world’s poorest people by turning sound energy into electricity. The process, known as thermo-acoustics, converts heat from biomass fuels into sound – and then into electrical energy.
The creation of a Stove for
Cooking, Refrigeration and
Electricity not only gave the project its name – the Score stove project – it also gave hope to some of the three billion people around the world who still cook on an open fire, resulting in at least four million premature deaths each year from smoke inhalation, according to the World
Health Organisation.
Dr Riley says EPSRC, which leads the
Research Councils UK Energy Programme, set up to tackle global energy challenges, had identified rural fuel use in poor areas as a priority and had set up a workshop to discuss solutions. He explains: “I knew that thermo-acoustics has no moving parts, so it could be made cheaply. Following the workshop I assembled a multidisciplinary team of colleagues from several universities and brought them together with the charity Practical Action to research and develop the technology.”
In 2010, the first Score Centre was set up in
Malaysia and ramped up its research with the aid of three doctoral students.
Twelve clean burning stoves (not electrically generating) were installed in Kenya and results published.
In 2011, Score Centres in Bangladesh, at the University of Engineering and
Technology (BUET), and in Nepal, at
Kathmandu University, were set up. Field trials in Nepal and Kenya were reported, confirming the need for a technology that generated as little as 10 Watts of electricity.
The main uses were seen as being for lighting, radio and charging mobile phones.
In 2012, an international conference was held to disseminate the work of Score, and people from five continents attended.
In the same year, the Score stove project received a second round of EPSRC funding to install more devices in developing countries’ universities. Electricity generating stoves were sent to
Kathmandu and Bangladesh universities, and Kenya installed
75 clean wood burning stoves.
Kathmandu University, with the support of Dr Riley and his team, successfully used the stove to produce electricity and boil water.
The Practical Action charity’s
Teo Sanchez says: “Partnerships like this, which combine active involvement of academics and non-academics from north and south with effective exchange of knowledge and know-how, contribute to real solutions to help the poor to use technology to challenge their poverty.”
In 2013, Paul Riley and his team won
Siemens’ Empowering People award for the Score stove technology and secured further funding to develop the technology in the field.
Work has still to be done on developing a stove more adapted and appropriate to the local conditions.
Dr Riley hopes that, by making it easier to build and more reliable, the Score stove will be transformed from highly promising device to life-saving invention.
Above: Score team members test out the stove in Kenya.
EPSRC 1994-2014 May 3: British child Madeleine McCann disappears from an apartment in Praia da Luz, Portugal
79

2007
In 2007, Encos, a spin out company from the
University of Leeds, was formed to develop carbon neutral masonry products made from waste products. The blocks literally lock carbon into the fabric of buildings. The research behind the company’s formation was developed by Dr John Forth and Dr
Salah Zoorob, and funded by EPSRC.
Dubbed Bitublock, the new building blocks used 100 per cent recycled and waste materials as the aggregate, bound together by bitumen, a heavy by-product of the petrochemical industry.
Using a low-energy process, Encos’s products are manufactured from recovered aggregates and a patented vegetable oilbased binder, encosol™. The result is net carbon neutral bricks and building slips with the looks, strength and performance of their traditional counterparts, without the environmental impacts.
In 2007, EPSRC co-invested in a joint initiative with the Helen Hamlyn Centre for Design and the Royal Academy of Art to create a new ambulance interior fit for
21st century healthcare.
The project brought together frontline paramedics, clinicians, patients, academic researchers, engineers, designers and potential purchasers in a co-design process, specifically looking at ways to provide healthcare in the community, reducing hospital admissions and patient journeys.
The new ambulance’s redesign focused on improving clinical efficiency and enhancing patient safety.
Among the changes were better located equipment storage spaces and an easilycleaned interior, making infection control much simpler and more effective. The vehicles were also equipped with some of the latest mobile communications
EPSRC 1994-2014 technologies including patient vital signs monitoring and hospital data transfer to specialist stroke, cardiac or trauma units.
Possibly the design change with the biggest impact was the decision to move the stretcher from its traditional position against the side of the ambulance and place it in the centre. This gave emergency teams 360 degree access to the patient.
The new design proved a hit with staff.
In 2011, Encos commissioned a £200,000 test plant at Yorkshire Water’s Knostrop site in Leeds, where it began producing carbon-negative masonry from incinerated sewage. The bricks were subsequently used to build several test walls at Poundbury
– the experimental urban development in
Dorset designed according to architectural principles advocated by the Prince of Wales.
In 2011, a full-size mobile demonstrator of the new ambulance interior was formally launched and went on the road.
Modular equipment packs containing specific treatment consumables were incorporated to aid clinical performance, infection control and stock control.
In 2012, the 21st century ambulance project won the Industrial Designers Society of
America Silver Award for Research at the
International Design Excellence Awards.
In 2012, the award-winning company conducted successful full scale manufacturing trials working with independent construction materials manufacturer S. Morris Ltd in Somerset.
December 20: Her Majesty Queen Elizabeth II becomes the oldest ever monarch of the United Kingdom
In 2013, Encos began a partnership with
Columbia Machine, a world-leading manufacturer of concrete products equipment, to bring its products to the mainstream market.
80

In 2007, spin out company Arvia Technology was formed to commercialise EPSRCsupported research into water treatment at
The University of Manchester by Dr Nigel
Brown and Dr Ted Roberts.
Arvia’s formation followed proof of principle funding from EPSRC in 2001, which later awarded follow-on funding to the company.
Arvia’s patented water treatment method removes and destroys organic contaminants and oils using a procedure that is free of process chemicals, is energy efficient, and produces little solid or liquid waste for disposal, using a unique adsorption material called Nyex®.
Since its formation, the company has received a host of awards and commendations and in 2009 featured in The
Guardian’s Global Cleantech 100 listing.
In 2010, Arvia secured investments of
£3.8 million to develop its nuclear and water business.
Today, Arvia is collaborating with the UK’s
National Nuclear Laboratory on a project using its technology to destroy oils and solvents contaminated by high levels of radiation currently located at the
Sellafield site.
In 2007, an EPSRCsupported Queen’s
University Belfast (QUB) lecturer, Dr Maire McLoone
(later O’Neill), was named
British Female Inventor of the Year at the British
Female Inventors and Innovators awards.
She received the award for a product that enhances security mechanisms to protect the public from cyber criminals, such as hackers, and also helps to identify thieves.
Maire O’Neill went on to become the youngest ever professor to be appointed at Queen’s at the age of 32. She was instrumental in the creation of the Centre for Secure Information Technologies (CSIT), an EPSRC Innovation and Knowledge
Centre (see page 77) at QUB, which has established strong links with global security organisations.
In 2014, Professor O’Neill received the
Royal Academy of Engineering Silver
Medal, one of only five engineers who have received the medal in national recognition of their contribution to society.
Today, Professor O’Neill’s invention is used in more than 100 million TV set-top boxes, and she is widely regarded as one of Europe’s leading cryptography experts, helping enhance global data security.
EPSRC 1994-2014
In 2007, Professor David Russell from the
University of East Anglia founded a spin out company, Intelligent Fingerprinting Ltd, based on his EPSRC-supported research into the detection of drugs and drug metabolites in fingerprints.
The company specialises in the development of non-invasive diagnostic screening technology for fast and convenient point-of-care testing using fingerprints.
The company has attracted worldwide interest in its technology for a wide range of drug-screening applications including criminal justice, drug rehabilitation, prisons and the workplace. The technique has potential for many other uses including healthcare diagnostics and homeland security applications.
In 2009, Professor Russell received followon funding from EPSRC to develop biomolecules that specifically bind to residues in forensic evidence which will prove the presence or absence of illicit substances.
In 2012, Intelligent Fingerprinting received an investment of £2 million from US backers, and over the next 15 months secured almost £700,000 in governmentfunded grants.
In 2014, Intelligent Fingerprinting secured
£750,000 in funding from a consortium of private US-based investors to support the final stages of development of the world’s first handheld fingerprint-based drug screening device, which is able to screen for multiple drugs and provides results in less than 10 minutes.
Simple to operate and totally noninvasive, the device is ideal for a variety of drug screening applications including drug rehabilitation services, offender management and criminal justice. The product is currently in development and will be available in 2015. The global market for drug screening was recently estimated to reach US$2.6 billion by 2015.
April 3: French TGV high speed passenger train breaks the speed record of the fastest conventional train, clocking 357.2mph
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2008
EPSRC 1994-2014 September 15: Lehman Brothers files for Chapter 11 bankruptcy protection, laying the catalyst for the global financial crisis
82

In 2008, Surrey Satellite Technology The company, whose Group Executive
Limited (SSTL),a company set up in 1985 to commercialise EPSRC-funded research led by Professor Martin Sweeting at the
University of Surrey, was sold to space technology giant EADS Astrium for
£40 million.
Chairman is Professor Sir Martin Sweeting
FRS, continues to work closely with the
University of Surrey, mainly through the
Surrey Space Centre, a dedicated facility borne out of research at the university.
Today, SSTL is the world’s leading small satellite company, with over 500 staff and export sales of over £150 million.
The company designs, manufactures and operates high performance satellites and ground systems for a range of applications including Earth observation, science and communications – at a fraction of the price normally associated with space missions.
In 2013, in a world-first space mission destined to make space exploration more accessible, a University of Surrey research team, led by Dr Chris Bridges, formerly an EPSRC-supported doctoral student, in collaboration with SSTL, developed the
STRaND-1 nano-satellite – made from an unmodified Google Nexus smartphone and built using advanced commercial off-theshelf components.
Since 1981, SSTL has built and launched over 40 satellites, and has developed an innovative approach that is changing the economics of space. It also provides training and development programmes, consultancy services, and mission studies for the European Space Agency, NASA, international governments and commercial customers.
The satellite made its maiden voyage aboard the Indian Space Research
Organisation’s Polar Satellite Launch
Vehicle, and is currently orbiting the Earth at around 16,000 miles per hour. It will be the first test of whether commercial elements and components found in everyday devices can survive in the extreme conditions experienced in space.
The satellite’s onboard computer checks which components of the phone are working normally and relays images and messages back to Earth via a radio system. In phase two of the programme, the STRaND-1 team hope to switch the satellite’s in-orbit operations to the phone, testing the capabilities of a number of standard smartphone components for a space environment.
Among the pioneering technologies developed for the mission is its WARP
DRiVE (Water Alcohol Resistojet
Propulsion system), a novel new propulsion system that will help the satellite to perform manoeuvres.
In 2014, SSTL supplied navigation payloads for the first two Galileo Full Operational
Capability spacecraft launched for a landmark European satellite navigation programme led by the European Space
Agency (ESA). Galileo is Europe’s own global satellite navigation system.
Ultimately, it will consist of 30 satellites and their ground infrastructure.
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EPSRC 1994-2014 July 28: The historic Weston-Super-Mare Grand Pier burns down for a second time in 80 years

2008
In 2008, EPSRC co-invested in two major healthcare initiatives with two new Strategic Partners, Cancer Research UK and the
Wellcome Trust.
With Cancer Research UK, EPSRC co-invested £45 million in medical imaging research to support the development and introduction of the latest cancer imaging technologies. The investment included £5 million from the Medical Research Council
(MRC) and the Department of Health for England.
Four large cancer imaging centres were established to serve as focal points in techniques such as Magnetic Resonance Imaging and Positron Emission Tomography. Five cancer imaging research programmes were also set up to concentrate on a specific area of imaging research.
In six years the multidisciplinary centres have established themselves as world-leading facilities in cancer imaging, whose breakthrough technologies include new techniques to enable noninvasive assessment of disease progression.
The £45 million co-investment with the Wellcome Trust led to the creation of four UK Centres of Excellence in Medical Engineering in June 2009. The centres, which are based at Imperial College
London, the University of Leeds, the University of Oxford and
King’s College London, focus on finding new solutions for arthritis; medical imaging; personalised healthcare; new medical devices and regenerative therapies.
In 2013, EPSRC strengthened its Strategic Partnerships with
CRUK and the Wellcome Trust with two new major investments.
With CRUK, £35 million was invested in four university-based centres to develop cutting-edge imaging technologies for basic and clinical cancer research. The total investment is now £116 million.
With the Wellcome Trust, £30 million was invested in a range of leading-edge research projects including computer-guided ultrasound technologies, and ways to transform the safety and efficacy of foetal surgery. The total co-investment is now £75 million.
Since 2000, EPSRC has forged a network of Strategic
Partnerships with blue-chip global industries and other ‘research users’, such as major charities and UK
Government departments.
Strategic Partnerships provide a key link between the needs of research users, such as industry, and long-term academic research. They also provide joint funding of UK universities to support research, training and other activities in gap areas of strategic importance to UK economic and social wellbeing; and enable clear routes to exploitation.
Beyond the major Strategic Partnerships, such are the benefits of working with collaborators from industry and other sectors that 45 per cent of EPSRC’s research portfolio is collaborative.
EPSRC works with around 2,800 companies and partner organisations. By ensuring the early engagement between industry and the research base, the fruits of EPSRC’s investments can be maximised, helping to keep the UK at the forefront of global research and innovation.
EPSRC 1994-2014 August 16: Usain Bolt sets a new 100 metres dash world record of 9.69 seconds at the Beijing 2008 summer Olympics
84

In 2008, a multidisciplinary
EPSRC-funded research team, led by Professor
Paul Sermon, a nanomaterials engineer at Brunel
University, devised an ingenious new bullet tagging technology that could make it much harder for criminals who use firearms to evade justice in future.
The tags primarily consisted of naturallyoccurring pollen, a substance that evolution has provided with extraordinary adhesive properties.
The tiny tags, which are invisible to the naked eye, are designed to be coated onto gun cartridges. They then attach themselves to the hands or gloves of anyone handling the cartridge and are very difficult to wash off completely.
Crucially, some of these ‘nanotags’ also remain on the cartridge even after it has been fired.
This research helped paved the way for ways to establish a robust forensic link
In 2008, wheels were set in motion to build the fastest car in the world, Bloodhound
SSC, capable of 1,000mph – 30 per cent faster than any car that has gone before.
In addition to setting a new World Land
Speed Record, the project has two other goals: to inspire the next generation about science, technology, engineering and mathematics; and to share an iconic research and development programme with a global audience.
Bloodhound SSC is a jet and rocket powered car weighing over seven tonnes. Its engines produce over 135,000 horsepower – six times the power of a combined starting grid of
Formula 1 cars.
The only other manned vehicles capable of exceeding 1,000 mph within Earth’s atmosphere are military fighter jets, although none can do this speed close to the ground where the air is thicker.
EPSRC 1994-2014 between a cartridge fired during a crime and whoever handled the cartridge.
The project was a joint collaboration between Brighton, Brunel, Cranfield,
Surrey and York universities.
In 2012, the team came up with a refined version of the technology.
After years of testing, they hit on a technique that could also stash away skin cells of any person touching the bullets, to increase the probability of obtaining useful associative evidence.
To label the hands of anyone who touches the bullet, they took the sticky pollen grains from the Easter lily, and coated them in titanium dioxide (TiO
2
) before dropping them in liquid plastic.
This solution was used to coat the bottom of the bullet casing. While the pollen is not uncommon, and TiO
2
is found in paints and sun lotions, together they form a unique tag, says Professor Sermon.
When tested on coatings on bullets from a nine millimetre Browning pistol, the team found that 53 per cent more viable DNA could be harvested from these bullets than from uncoated ones.
An EPSRC-funded aerodynamics team at
Swansea University have played a vital role in the project, which EPSRC has sponsored since launch. Swansea’s Dr Ben Evans says:
“Wind tunnels have massive limitations.
Bloodhound is a car, so it’s rolling on the ground. There are no wind tunnels where you can simulate this with a car travelling faster than the speed of sound. Our job is to make sure the vehicle stays on the ground, and that the drag is as low as possible.”
In 2015 , the Bloodhound team, led by
Richard Noble OBE, will begin its attempt on the World Land Speed Record.
In 2008, EPSRC-supported engineers at the
University of Leeds co-developed a device to help some of the most impoverished farmers in Africa maximise crop yields.
The device gathers data on air temperature, humidity, air pressure, light, soil moisture and temperature – information crucial to making key agricultural decisions about planting, fertilisation, irrigation, pest and disease control and harvesting.
The research team, led by Professor Jaafar
Elmirghani, worked with two Kenyan villages to develop the technology, funded under the Research Councils UK Digital Economy
Programme, led by EPSRC.
The devices fed back information via a wireless network to a central hub, or server, located at the village school, which was then sent to agriculture experts to assist farmers’ decision-making. The data was also fed into agricultural teaching at Kenyan schools.
This project was led by the London
Knowledge Lab, and involved UK researchers working with the University of
Nairobi, and with rural communities in Kenya.
Today, Professor Elmirghani leads the
£6 million INTelligent EneRgy aware
NETworks (INTERNET) research project in collaboration with colleagues at the
University of Cambridge and a number of major industrial players. The five-year project is funded by EPSRC.
September 10: The Large Hadron Collider at CERN, described as the biggest scientific experiment in the history of mankind, is powered up in Geneva
85

2008 of an industry and academic partnership producing world-class research for the benefit of the environment and the car buyer.
“The most important part of the project is that the technologies developed are available and affordable and, as we have already shown, can be easily implemented into next-generation models to produce lower emissions.”
In 2008, a major collaborative research partnership between Research Councils
UK and Indian agencies was launched.
The initiative set up a dedicated Delhibased programme, RCUK India, which was set up to address major global challenges.
In 2008, a multidisciplinary collaboration between EPSRC-supported engineers and industry partners resulted in a concept car engine that reduces fuel consumption by
15 per cent.
The award-winning system, which sprays fuel directly into the cylinders of a petrol engine rather than using a fuel/air mix, attracted interest from a number of major car manufacturers.
The project, led by Professor Nicos
Ladommatos, from University College
London (UCL), was a collaboration between
UCL, Loughborough University, Lotus
Engineering and Continental Powertrain.
Interviewed in 2008, Mike Kimberley,
Chief Executive Officer of Group Lotus Plc, said: “The project is an excellent example
The affordable technology caught the interest of the car industry, and also won the Automotive category at The Engineer magazine’s Technology and Innovation
Awards 2008.
In 2009, the work on the Hotfire project was completed, and some of the technologies developed were taken forward by
Lotus Engineering in subsequent engine development.
In 2015, Professor Ladomattos and colleagues at UCL begin a new EPSRCfunded project, working with the University of Brighton, investigating ultra efficient engines and fuels. A project partner in the research is UK car manufacturer Jaguar
Land Rover (JLR) with which the university has had a long-term collaboration, supporting its advanced engine research programmes.
EPSRC is heavily involved in the initiative, which spans energy security, food, arts, humanities, social sciences, water & climate change, chronic disease and sustainable crop production.
Projects co-funded by EPSRC include research into advanced manufacturing; smart energy grids and storage; and sustainable energy.
In just six years the joint research programme had gone from an almost zero base to close to £150 million in jointly-funded UK-India projects.
In 2008, at the age of 27,
Olga Kubassova, a former
EPSRC-sponsored doctoral student at the University of Leeds, founded medical software company Image
Analysis to commercialise her research. In 2008, EPSRC launched HECToR, the largest and most advanced supercomputing facility in the UK.
Based at the University of Edinburgh’s
Advanced Computing Facility, the
£113 million service ran for six years and was managed by EPSRC on behalf of the
UK Research Councils. and encouraged industry and commerce to make effective use of high-end computing.
As one of the largest and most advanced supercomputers in Europe, HECToR played a key role in keeping researchers at the forefront of their fields. Its work included forecasting the impact of climate change, modelling fluctuations in ocean currents, projecting the spread of epidemics, designing new materials and developing new medicinal drugs.
The company’s image analysis platform,
Dynamika, allows clinicians a vital window of opportunity to treat arthritis and other inflammatory diseases in its early stages. It does this by turning the abstract concept of algorithms into innovative software to enable repeatable and reliable early diagnosis.
The software is now used in hospitals and clinical departments across Europe, and
Image Analysis has grown to employ 25 staff.
The new supercomputer, which was capable of making 63 million, million calculations per second – 10,000 for every person on the planet – provided a worldclass, internationally accessible service for
UK-based academic research.
HECToR also supported the development of innovative computational technologies
EPSRC 1994-2014
In 2014, HECToR was decommissioned and replaced by the ARCHER supercomputer, one of the fastest on the planet.
You can find out more about HECToR in
Pioneer 12.
In 2012, Olga Kubassova (pictured) was named Entrepreneur of the Year at the
Everywoman in Technology Awards, and in
2014 Image Analysis was featured as Wired magazine’s Start-up of the Week.
August 17: Michael Phelps surpasses Mark Spitz in Gold Medals won at a single Olympics, winning eight in total
86

The year 2008 marked the highly significant fourth anniversary of an enduring research partnership between four scientists from different disciplines: Professors Lee Cronin, from the University of Glasgow, Natalio
Krasnogor and Cameron Alexander, from
The University of Nottingham, and Ben
Davis from the University of Oxford, who met during a 2004 EPSRC-sponsored ‘Sandpit’ creative workshop aimed at promoting bluesky, curiosity-led research.
The Sandpit, one of the first in a new generation of creative workshops, focused on the potential development of synthetic chemical-cells, or CHELLS, a phrase coined at the workshop and now adopted in many scientific and popular articles on synthetic biology.
Following on from the Sandpit, Professors
Alexander, Krasnogor, Davis and
Cronin co-authored a discussion piece in Nature Biotechnology with fellow
Sandpit participants proposing a ‘thought experiment’ to determine whether an artificial cell is alive. This led to a thoughtprovoking film with designer James King,
The Imitation Game. And so the Chellnet network was born.
The film was the first product of a remarkable multidisciplinary collaboration between the four scientists, which, through individual and joint research projects, took three approaches to the CHELL concept: polymeric, chemical biological and inorganic.
These projects explored, in different and complementary directions, ways to understand how cellular structures might imitate a living system, and the profound impact this might have. All four scientists have since contributed important advances in synthetic, chemical and computational biology research.
In 2008, chemist Cameron Alexander, who has steered his research towards medical uses for CHELL technology, working with doctoral student George Pasparakis, took some initial steps towards creating a synthetic copycat of a living cell, using long-chain molecules to mimic the surfaces of the real thing.
The EPSRC-supported research could one day lead to new targeted drug delivery systems, where the artificial cell capsules carry drug molecules to attack specific diseased cells in the body, while leaving healthy cells intact. It could thus offer a new weapon in the fight against superbugs.
In 2009, supported by an EPSRC Platform
Grant, chemical biologist Professor Ben
Davis and Paul Gardner, from the Davis research group, constructed a lipid-bound
‘protometabolism’ that synthesises complex carbohydrates from simple raw materials.
This encapsulated system may represent the first step towards the realisation of a synthetic chemical cell that displays complex behaviours such as communication with natural cells.
All four founding members of Chellnet provided input into this research; Davis has also worked with Cameron Alexander on the development of polymer CHELLS.
In 2011, Natalio Krasnogor, at the time working at The University of Nottingham’s
School of Computer Science, began an ambitious EPSRC-funded project that takes a synthetic biology approach to developing a biological cell equivalent of a computer operation system. If successful, the research will lead to a ‘re-programmable cell’ within a living organism. Not only would this revolutionise synthetic biology, it would pave the way for scientists to utilise biology as a next-generation platform from which to build a
‘biological computer’.
Now at Newcastle University, where he is professor of computer science and synthetic biology, Krasnogor’s expertise in synthetic biology has helped to unify the diverse projects conducted by the Chellnet.
In 2011, Lee Cronin and his team of EPSRC-supported scientists took their first tentative steps towards creating ‘life’ from inorganic chemicals, potentially defining the new area of ‘inorganic biology’.
The inorganic cells, which can store electrons similar to a battery, and also harvest solar energy, could potentially be used in numerous medical applications in medicine, as sensors or to confine chemical reactions. By taking a ‘minimal’ approach to the assembly of inorganic CHELLS they hope to understand how living systems can spontaneously emerge in the
‘inorganic’ world.
The Cronin group’s aims are ambitious: to engineer/discover routes to artificial life. These routes may also be relevant to determining the origin of life on Earth and to understanding how easy (or hard) it could be for the emergence of life elsewhere.
In December 2014, Cronin’s team reported it had succeeded in creating an abiotic evolving chemical system for the first time.
The process uses a robotic ‘aid’ and could be used in the future to ‘evolve’ new chemicals capable of performing specific tasks.
All stemming from a creative thinking workshop the like of which none of the four scientists had experienced before (see page
58), and which set them on a journey of discovery which could lead to new forms of life – but not quite as we know them.
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EPSRC 1994-2014 November 11: The RMS Queen Elizabeth 2 (QE2) set sail on her final voyage to Dubai

2009
In 2009, in a bold new approach to doctoral student training, EPSRC invested
£250 million in 44 all-new Centres for
Doctoral Training (CDTs).
It was the biggest-ever single investment in training scientists and engineers and led to comprehensive ‘cohort-based’ training for over 2,000 doctoral students, tackling some of the biggest problems facing the UK and the planet, such as climate change, energy, an ageing population and high-tech crime.
Such has been the success of the initiative,
EPSRC has continued to develop the programme, particularly through a major new tranche of investment in 2014.
There are now 115 new CDTs in
33 universities, training over 7,000 postgraduates on specific research challenges, such as cybersecurity, renewable energy, robotics and applied photonics.
Based on a series of successful pilot schemes in ‘cohort-based’ doctoral training, begun in 2002, the initiative created communities of researchers, bringing together diverse areas of expertise to train engineers and scientists with the skills, knowledge and confidence to tackle today’s evolving issues.
Centres for Doctoral Training create new working cultures, build relationships between teams in universities and forge lasting links with industry, providing clear pathways and opportunities for businesses and universities to work together. Today there are 1,000 partner companies – from global megabrands such as P&G and Tata
Steel to SMEs.
Combined governmental and partner funding for CDTs is now £962 million, including £31 million in capital investment.
It is the UK’s largest investment in postgraduate training, in areas of key importance to the UK economy and society, representing perhaps the biggest industry-educational trans-sector training investment in Europe.
EPSRC Associate Director, Dr Alison
Wall, says: “Cohort-based training such as this brings people together to look at real-world problems. They don’t just focus on areas of concern to GSK or
Rolls-Royce, they will often have 10-20 companies working on problems. They see commonalities of approach, which are usually multidisciplinary, and they develop multiple solutions.
“More than 40 per cent of CDT studentships are collaborative with a company from the very start. Students work with business and other mentors and some may spend most of their time in a company.
“We also help to provide students with the skills that might lead them to become entrepreneurs. This is training for the business environment.
“Nearly half of all EPSRC-supported students go into business straight after their doctorate, and most will end up working in business and government for their longer-term career.”
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EPSRC 1994-2014 January 3: Israeli ground forces invade Gaza

EPSRC 1994-2014 January 20: Barack Obama is inaugurated as the 44th President of the United States of America, becoming the first African-American president
89

2009
EPSRC 1994-2014 June 1: Air France Flight 447 crashes into the Atlantic Ocean, en route from Rio de Janeiro, killing all 228 on board
90

In 2009, an EPSRC-supported team from the University of Warwick, led by Dr Kerry
Kirwan, an EPSRC Challenging Engineering award holder, designed and built the world’s first fully sustainable Formula 3 racing car.
The WorldF3st (pictured) is made from woven flax, recycled carbon fibre, recycled resin and carrot pulp for the steering wheel.
It runs on biofuel made from chocolate and animal fats and is lubricated with plant oils.
It is both environmentally friendly and fast, and can achieve 0-60 in 2.5 seconds before reaching a top speed of 175 mph.
The car was launched at the 2009
Goodwood Festival of Speed, showcased at the British
Grand Prix and later demonstrated at the
European Grand Prix.
In 2009, WorldF3st was featured as one of
TIME Magazine’s Top 50 Global Inventions.
In 2010, the research team were short-listed for Times Higher Education magazine’s award for Outstanding Engineering
Research Team of the Year.
In 2013, EPSRC funded further research at
Warwick to develop recycled composites and flax-reinforced composites for the Lola-
Drayson all-electric prototype racing car, demonstrating the potential of sustainable technologies in the motorsport industry.
The car later broke the World Land Speed
Record for a lightweight electric car, hitting a top speed of 204.2 mph at a racetrack at
RAF Elvington in Yorkshire.
Also in 2013, a multidisciplinary, multiuniversity team led by Dr Kirwan began a £3 million, three-year EPSRC-funded project aimed at using plants and bacteria to recover useful materials, such as platinum, nickel and arsenic, from contaminated land.
Working with a University of Edinburgh team, led by Dr Louise Horsfall, the team use fungi and bacteria to degrade the plant biomass, a process which unlocks the metals the plants have accumulated.
The bacteria ingest the metals, forming metallic nanoparticles for later extraction.
With the fungi the bacteria also produce chemicals and other products for the pharmaceutical industry.
The idea for the project emerged from an EPSRC ‘Sandpit’ creative thinking workshop (see page 58) involving scientists from Newcastle, Birmingham, Cranfield,
Edinburgh and Warwick universities.
Today, Dr Kerry Kirwan is Director of the EPSRC Centre for Doctoral
Training in Sustainable Materials and Manufacturing at the University of Warwick.
He is also
Strategic
Director of the
Industrial
Doctorate
Centre and
Head of the
Sustainable Materials and Manufacturing
Research Group within
Warwick Manufacturing
Group. Dr Kirwan also leads the university’s Global Research Priority in
Innovative Manufacturing.
PIONEER 14 Winter 2014 June 25: The death of American entertainer Michael Jackson triggers an outpouring of worldwide grief
91

2009
In 2009, EPSRC-supported scientists and preservation experts joined forces to help save historic York Minster Cathedral from decay and erosion.
Researchers co-funded by EPSRC and the
Arts and Humanities Research Council
(AHRC) at the Universities of York and
Cardiff used advanced X-ray techniques to investigate the composition of the limestone and historic mortars used to build York Minster, and the ways in which these have decayed as a result of weathering and pollution over time.
EPSRC 1994-2014
Through their research, the project team, led by Dr Karen Wilson from Cardiff
University, were able to provide crucial advice to conservation experts on how best to treat the stone to prevent further decay.
They also advised on the most suitable materials to be used in the restoration of
York Minster’s East Front.
In 2012, a team led by Dr Karen Wilson and her fellow Cardiff colleague, Professor
Adam Lee, developed a new treatment that could help protect historic limestone buildings from erosion.
Working on York Minster’s iconic magnesian limestone cathedral, the team developed a new treatment, utilising hydrophobic surface coatings, which protects limestone from erosion by acid rain and atmospheric pollutants, while allowing the stone to ‘breathe’.
Findings from the project, which was conducted under the auspices of the
Science and Heritage Programme cofunded by EPSRC and AHRC, could now be used to help conserve other historic limestone buildings around the world.
January 19: The UK Government confirms a £300-billion bailout package for the United Kingdom’s banking industry
92

In 2009, EPSRC-funded researchers at the University of Leeds embarked on the 50 Active Years after 50 ® healthcare technologies initiative, focused on regenerative therapies such as joint and organ replacements. Its aim was to help ensure people can live as actively up to 100 years of age as they did up to
50 years.
The group’s work includes developing longer-lasting joint replacements for the hip, knee and spine; bio-regenerative scaffolds for tissue regeneration in areas such as heart valves, blood vessels, meniscus and ligaments; enhancing the quality and reliability of devices such as implants and biomaterials and advancing stem cell therapies.
Based within the prestigious Institute of
Medical and Biological Engineering at Leeds, the research team, led by Professors John
Fisher and Eileen Ingham, is addressing these challenges through seven major centres and EPSRC Programme Grants.
The centres include the EPSRC
Centre for Doctoral Training in Tissue
Engineering and Regenerative Medicine; the EPSRC/Wellcome Trust-supported
WELMEC Centre of Excellence in Medical
Engineering; and the EPSRC-supported
Innovation and Knowledge Centre (IKC) in
Regenerative Therapies and Devices.
With his team, Professor Fisher, a member of EPSRC Council, its senior decision-making body, has pioneered work on longer-lasting joint replacements, revolutionary spinal interventions and a new generation of biological scaffolds for tissue repair that grow with the body.
The Medical Technologies IKC alone has attracted over £90 million in research and innovation funding, as well as over
£50 million in private sector investment in product development (see page 77).
Successful IKC projects have included a portable heart scanner, new surgical technologies and an award-winning product that can reverse early-stage tooth decay. The research that led to this product was funded by EPSRC, beginning in the 1990s.
In 2013, the EPSRC Centre for Innovative
Manufacturing in Medical Devices was inaugurated at the University of Leeds. The centre dovetails with the Medical Technologies
Innovation and Knowledge Centre.
In 2009, cutting-edge computer modelling software brought an extinct, trumpet-like instrument back to life – allowing a work by Bach to be performed as the composer intended for the first time in nearly 300 years.
No one alive had heard, played or even seen a picture of the lituus – a two-metre long horn made from beech. It was recreated thanks to software developed by Dr Alistair
Braden, an EPSRC-supported doctoral student at the University of Edinburgh.
Schola Cantorum Basiliensis, a Swissbased music conservatory specialising in
EPSRC 1994-2014 early music, used Edinburgh’s designs to build two identical examples of the longlost instrument. Both were later used in an experimental Bach performance.
The research opened up the potential for tailor-made musical instruments to suit the individual needs of musicians.
The project also has potential applications in structural engineering. For example, acoustic signals could be sent through hardto-reach pipework and ducting in buildings such as power stations to reveal their condition accurately.
January 21: Toyota surpasses General Motors to become the world’s largest car maker
In 2009, EPSRC introduced its
Knowledge Transfer Account programme, which saw investment of £55 million in 25 university-led projects focusing on grants to help further exploit the outputs of
EPSRC-funded research.
Universities were given the flexibility to use their KTA funding in areas such as proof-of-concept funding, entrepreneurship training, networking, people exchange, business relationship-building and start-up generation.
Among many successful projects, a team from Newcastle University used their Knowledge Transfer Account funding to develop an ultra low-cost pre-natal scanner that uses pulses of high frequency sound to build up a picture of the unborn child on a computer screen.
Conventional ultrasound scanners can cost up to £100,000, but the device can be manufactured for as little as £40.
In 2012, Knowledge Transfer
Accounts were replaced by Impact
Acceleration Accounts , which build on the KTA concept.
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2009
In 2009, following a successful blue-sky thinking ‘Sandpit’ exercise (see pages 80-
83) , EPSRC and the United States National
Science Foundation (NSF) co-invested
£6 million in five new collaborative research projects between UK and US researchers in the emerging field of synthetic biology – a new approach to engineering biology.
Still in its infancy, synthetic biology could revolutionise how we make things – from innovative biofuels to a new generation of antibodies and vaccines – and the research projects launched under the initiative covered areas ranging from biological and chemical engineering to plant biology and sociology.
The Sandpit concept was subsequently adopted by the NSF and by other UK research councils – inspired by the creative thinking it unlocked.
In 2009, EPSRC and the Biotechnology and Biological Sciences Research Council
(BBSRC), held a year-long series of public workshops and stakeholder interviews on the science and issues surrounding synthetic biology, and helped to articulate some important questions for those developing the field.
In 2009, EPSRC co-invested in the Centre for Synthetic Biology and Innovation at
Imperial College London under its Science and Innovation Awards initiative (see page 68). The centre is developing the foundational tools for synthetic biology and using these to generate innovative biological applications in healthcare and industry.
In 2013, EPSRC invested in the SynbiCITE
Innovation and Knowledge Centre (see page 77), led by Imperial College London.
With funding from BBSRC and the
Technology Strategy Board (now Innovate
UK), the centre aims to serve as a national resource integrating university and industry-based research in synthetic biology and to accelerate this into industrial processes and products.
It also functions as a vehicle for the support of UK SMEs and startup companies.
Since its formation, the centre has generated over £4.5 million in additional research income.
In 2014, a multidisciplinary
UK/US research team published
Synthetic Aesthetics, a book resulting from their project of the same name emerging from the
2009 Sandpit event.
The book explores synthetic biology and the design of living systems, using design and art as a way to open up the discussion.
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EPSRC 1994-2014 October 2: Rio de Janeiro is elected as host city of the 2016 Summer Olympics and Paralympics

In 2009, research by EPSRC-sponsored engineers at Queen’s University Belfast’s
Institute of Electronics, Communications and Information Technology (ECIT), led by
Raymond Dickie, an Engineering Doctorate student funded by EPSRC, developed a high performance filter that will allow weather forecasters to make more accurate predictions.
The filters will be installed in European
Space Agency satellites for launch between
2018 and 2020, and will enable more accurate global weather forecasts to be compiled.
The filters will also help to provide important new insights into climate change.
ECIT’s research on Frequency Selective
Surface structures has led to major advances in the design and manufacture of the next generation of Earth observation satellites.
In 2009, a team of engineers at the University of Leeds, led by Professor Andrew Bell, developed a system to convert foot power into battery power for use by foot soldiers. The system could reduce the weight of troops’ packs by up to 10 kilogrammes. The devices use high-tech piezoelectric transducers to convert mechanical stress into electricity.
The project was part of a larger programme of research called the ‘battery free soldier’, commissioned by EPSRC and Dstl, which includes research into converting and storing other sources of energy such as solar power and body heat.
In 2011, Professor Bell and colleagues at
Leeds launched Ionix Advanced Technologies
Ltd to commercialise the research.
The company focuses on a range of devices based on high-temperature piezoelectric materials which could transform industry’s ability to electronically monitor and interact with extreme environments.
The products’ potential market in industries such as aerospace, oil and gas and nuclear power is estimated at more than £500 million per annum.
In 2014, Ionix received funding from Innovate
UK to accelerate the commercialisation of its products.
In 2009, an EPSRCfunded team at
Imperial College
London’s Department of Chemistry Cancer
Cells, led by EPSRC
Postdoctoral Fellow
Dr Marina Kuimova
(pictured), showed how cancer cells become ‘gloopy’ or viscous as they die – a discovery which could lead to a better understanding of how to treat cancer.
In 2009, Dr Kuimova won the Roscoe
Medal for Chemistry at the SET for
Britain awards, a national competition aimed at raising the profile of early-stage researchers.
In 2010, Dr Kuimova was awarded a five-year EPSRC Career Acceleration
Fellowship to continue her viscosityrelated research.
In 2012, she received the Royal Society of
Chemistry’s Harrison-Meldola Memorial
Prize for her pioneering studies in the spectroscopy and imaging of biological materials.
In 2014, Dr Kuimova was awarded the
International Union of Pure and Applied
Physics C6 Young Scientist Prize in recognition of her exceptional achievement in the field of biological physics.
In 2009, one of the most sophisticated aircraft simulators ever created – designed to mimic the flight deck of supersonic aircraft Concorde – was officially recommissioned at Brooklands Museum in
Surrey, four decades after the first British
Concorde made its maiden flight.
The simulator was brought back to life thanks to an EPSRC-supported public engagement project led by a team from the University of Surrey and involving experts from XPI Simulation and dozens of museum volunteers.
Today, the simulator helps explain to visitors the roles played by advanced technologies, and especially airframe and engine aerodynamics, in making Concorde the world’s only successful supersonic passenger transport.
The simulator, one of only two in the world, cost £3 million in 1975 (equivalent to over
£30 million today).
In 2009, a three-year study of over
7,000 academic journal articles showed that EPSRC-supported researchers achieve a higher than average citation rate of 1.6 compared to a UK average of
1.4 and a world average of only 1.0.
The higher rating reflected the impact that EPSRC-supported researchers have and also highlighted how competitive EPSRC-funded research is internationally.
EPSRC 1994-2014 February 1: The wreck of the British warship HMS Victory is discovered in the English Channel
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2010
In 2010, after years of research, Professor Mike
Charlton (pictured) and his team in the Physics
Department at Swansea
University made the firstever direct measurement of an atom of pure antihydrogen – the simplest form of antimatter.
This was no easy task. When matter and antimatter come into contact they instantly annihilate each other, making it very tricky to keep an atom of anti-hydrogen around long enough to look at it.
But the team, part of the wider ALPHA experiment at CERN seeking to make detailed observations of anti-hydrogen, developed a technique using magnetic fields to trap anti-atoms for up to half an hour (“an eternity for physicists” according to Mike Charlton), and easily long enough for them to be studied.
At stake in all this is nothing less than an understanding of why the universe exists at all. The picture that we have of how the universe began suggests that there should have been equal amounts of matter and antimatter created in the Big Bang. The lack of antimatter that we can see in the universe is a mystery.
By studying antimatter atoms, we may come to discover some of the tiny but fundamental asymmetries between particles of matter and antimatter, which may explain why they didn’t just cancel themselves out after the Big Bang, leaving a universe with nothing in it.
The ALPHA project breakthrough came after a period of more than 15 years, during which EPSRC supported teams from the physics departments of the universities of
Swansea, Liverpool and Manchester.
Mike Charlton says: “This was the culmination of many years of effort for the Swansea team and our colleagues.
EPSRC support helped us to put our teams together and also paid for specialist equipment. EPSRC has been by far the largest source of support for this work in the UK.”
In 1996, EPSRC was the first national research council anywhere in Europe to commit to the ATHENA project at CERN, which aimed to produce large amounts of anti-hydrogen atoms for the first time.
Mike Charlton says: “EPSRC took a chance in funding this highly speculative project in
1996. But its support acted as a catalyst, persuading other countries to contribute to the ATHENA consortium. EPSRC’s faith in the project was key to the success of this international collaboration.”
Given that CERN was the only place where research in this area could be carried out,
EPSRC’s support included a large number of travel grants, in addition to capital and other investments.
In 2002, the ATHENA consortium, within which Mike Charlton’s team played a pivotal role, achieved the world’s first controlled production of anti-hydrogen atoms. Though the atoms only lasted for a fraction of a second before annihilation, this paved the way for the later trapping experiments and now the detailed studies of their properties.
The 2002 breakthrough had been made possible thanks to EPSRC support for the
Swansea team over the previous six years, particularly through the development of a positron accumulator – a vital piece of equipment that enabled the breakthrough.
Built in the UK before being shipped over and installed at CERN, the accumulator was able to collect around 100 million positrons every three minutes, for use in anti-hydrogen experiments.
In 2013, EPSRC announced further support for Mike Charlton’s team, this time for
Dr Niels Madsen, a Reader in Physics at
Swansea University’s College of Science.
A £1.66 million grant will fund experiments to trap anti-hydrogen atoms for still longer periods of time, and to carry out further precision measurements of them. EPSRC support for the Swansea team’s research will continue at least up to 2017.
Antimatter has long been a staple of science fiction. We may not be about to see Star Trek-style warp engines any time soon, but thanks to Mike Charlton’s team we may soon be able to understand some fundamental aspects of the universe.
Mike Charlton says: “The epoch of
EPSRC support for this project, and its farsightedness in backing it when there was no guarantee that anyone else would, is a remarkable story in itself.”
EPSRC 1994-2014 January 4: The US Department of Health and Human Services, Centers for Disease Control and Prevention removes HIV infection from its list of communicable diseases of public health significance
96

EPSRC 1994-2014 February 24: News reports indicate that Europe risks a double-dip recession after bad results emerge from France, Germany and Italy, with the
Eurozone only growing by 0.1 per cent in the last quarter of 2009
97

2010
In 2010, ApaTech, an award-winning spin out company launched to commercialise
EPSRC-supported research by medical materials engineer Dr Karin Hing and
Professor William Bonfield at Queen
Mary, University of London, was acquired by global healthcare company Baxter
International for US$330 million.
The company was formed in 2001 with an initial investment of £3 million to commercialise pioneering research into synthetic bone substitutes.
The research, which led to a form of bone graft with enhanced structure and chemistry to boost healing, was developed at the EPSRC-supported Interdisciplinary
Research Centre in Biomedical Materials at
Queen Mary, University of London.
ApaTech became an object lesson in how innovative technology from a UK university can be developed and commercialised on a global scale. Several successful venture capital investment rounds underpinned significant expansion of the business including new manufacturing capacity. These enabled it to continue the development of its lead products, particularly its bone graft substitute,
Actifuse, which was successfully marketed in Europe, the United States and other select sectors around the world.
In 2007, ApaTech won the Business
Initiative Award at the Times Higher
Education Supplement awards.
In 2008, ApaTech received the Research and Development Award at the Tech Track awards, in recognition of the innovative and ground-breaking research which has underpinned the company’s growth.
In 2009, by now an acknowledged leader in synthetic bone materials for orthopaedic and dental applications, with a major manufacturing plant in the UK and growing sales world-wide, ApaTech generated sales of around US$60 million.
In the same year, the company was ranked number two in The Sunday Times Tech
Track 100 Fastest Growing Private Medical
Technology Companies listing.
In 2009, ApaTech was named fastestgrowing company in its category by
Deloitte’s Technology Fast 500 for Europe, the Middle East and Asia.
In 2011, Dr Karin Hing, a senior lecturer at Queen Mary, University of London, received a Royal Academy of Engineering
Silver Medal for her role as the ‘technical linchpin’ behind ApaTech.
EPSRC 1994-2014 April 20: The Deepwater Horizon oil drilling platform explodes in the Gulf of Mexico, killing 11 workers, resulting in one of the largest oil spills in history
98

In 2010, the first three state-of-theart EPSRC Centres for Innovative
Manufacturing (CIMs) were launched under a new £70 million EPSRC investment to help UK businesses develop the technology products of the future and underpin manufacturing growth.
Specifically the centres were tasked with enabling the commercial development of the key discoveries in university-based manufacturing research.
Based at Southampton, Loughborough and
Brunel universities, the EPSRC Centres focused respectively on research into photonics, regenerative medicine and liquid metals for reuse and recycling.
The new EPSRC Centres built on the success of the Innovative Manufacturing
Research Centre (IMRC) funding model, in place from 2001 until 2009, which saw
18 university-based centres receive an initial block grant for five years, with potential for up to a further five years.
By 2014, the number of EPSRC Centres for
Innovative Manufacturing across the UK had grown to 16, covering subject areas ranging from liquid metal manufacturing to additive manufacturing. Many of these centres’ directors hail from industry, or have a strong industrial background.
Some CIMs are focused on future products such as composites, food and pharma that will be especially important to the UK, and some investigate production technologies and how they scale up, such as additive manufacturing and automation.
EPSRC works very closely with Innovate
UK (formerly the Technology Strategy
Board). The CIMs and Innovate UK’s
Catapults – technology innovation centres
– have a particularly close symbiosis, often overlapping. The Catapults tackle the problems of today, EPSRC Centres for
Innovative Manufacturing research the solutions of the future.
Between them, the CIMs and Catapults cover more than 20 core fields of science, engineering and business. Together they are tackling key challenges for modern industry, including automation, the digital economy, future cities, continuous pharmaceutical manufacture, food, satellites, industrial sustainability, graphene engineering, sustainable feedstocks and much more.
EPSRC currently invests £80 million every year in UK manufacturing research
– mainly through its Manufacturing the
Future initiative. This programme has a portfolio of 230 projects representing an investment of over £350 million in cuttingedge work at the UK’s leading universities, and through collaboration with over
600 companies, which have contributed a further £136 million.
Together, the manufacturing researchers supported by EPSRC and the business partners they work with help decide which products and production methodologies the UK should focus on, and work out how to link the UK’s network of people and manufacturing processes.
In 2010, EPSRC awarded a four-year Career
Acceleration Fellowship to Dr Ioannis
Ieropoulos, from the Bristol Robotics
Laboratory (BRL), a University of Bristol/
University of the West England research facility, to develop his research into how waste could be used by microbial fuel cells (MFCs) to generate energy. Live microorganisms inside the fuel cell process the waste to produce electricity.
By 2010, the BRL team had already launched the third generation of EcoBot, a robot which can power itself by digesting waste. The early stage work of this research was funded by EPSRC.
A unique aspect of the team’s research is the use of urine as a waste material to power the MFCs. Every day, around
EPSRC 1994-2014
38 billion litres of urine are produced by humans and farm animals worldwide – the energy from which, they have shown, could potentially be harnessed by scaling up
MFCs into stacks.
Another aspect of the research is the use of waste from oxygen-producing organisms, such as algae, within a self-sustaining system through which the bacteria use their own waste to produce energy.
In 2013, claiming a world-first, Dr Ieropoulos and BRL colleagues used urine to produce electricity to charge a mobile phone, generating enough power to enable the phone to be used to make a brief call, send text messages and browse the internet.
In 2014, the Bill & Melinda Gates
Foundation awarded US$100,000 to BRL under the Grand Challenges Explorations
Scheme to fund the Urine-tricity project investigating generating electricity from urine and wastewater for countries of the developing world. The project is also funded by EPSRC.
Dr Ieropoulos (pictured above) says: “Not only is the technology we are developing a means of electricity generation, it can also improve sanitation. The work carried out under the EPSRC grant is primarily focused at developing this technology for the developed world.”
May 15: Aged just 16, Australian teenager Jessica Watson becomes the youngest person to sail non-stop and unassisted around the world solo
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2010
In 2010, the hidden secrets of some of the world’s most famous paintings were revealed, thanks to a partnership between
EPSRC and the National Gallery.
A state-of-the-art gas chromatographymass spectrometer (GC-MS), funded by
EPSRC, helped specialists in the National
Gallery’s science department study the organic chemistry of old master paintings to understand how paintings were made and how they have changed over time.
In painstaking investigations, the scientists used GC-MS to study the characterisation and composition of paint binding media, additions to paint media such as resins, and the composition of old varnishes.
The ground-breaking project culminated in the first major exhibition of its kind in summer 2010 and also featured in Pioneer.
In 2014, the partnership between EPSRC and the National Gallery led to EPSRC funding the purchase of a new state-ofthe-art high-tech easel that makes it possible to examine great works of art in unprecedented detail.
The computer-controlled easel is capable of safely holding a very large painting and moving it in minute steps to make the most of the latest digital technology.
Identifying the materials used as pigments provides information on aspects such as the age of a picture and the painting technique used.
Scientists and other researchers at the
National Gallery are using digital imaging to build up a high resolution image of paintings to learn about their structure, the way they are made and what needs to be done for their preservation.
The easel will open up opportunities to try out new types of research.
Ashok Roy, Director of Collections at the
National Gallery, says:“We expect we will be able to acquire very high resolution images in various parts of the spectrum that would be unobtainable without this technology, so it is a real advance in our imaging capabilities.”
The easel helped inspire part of the 2014
Making Colour exhibition, through which
National Gallery visitors were able to get involved in an interactive experiment that will feed into future research on human colour perception.
In 2010, Professor Andre Geim and
Dr Konstantin Novoselov, who were the first to isolate wonder-material graphene, in 2004, were awarded the
Nobel Prize in Physics for their work.
(see pages 50-53).
January 4: Anti-government protests in Tunisia and later other Arab nations begin. These protests become known collectively as the Arab Spring
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EPSRC 1994-2014

In 2010, EPSRC-supported researchers at the University of Birmingham, overseen by Professor Ian Norton, previously Chief
Scientist at Unilever, created a low-fat chocolate which is 60 per cent water – claiming it tastes as good as a normal bar.
The team replaced fat in foods with caloriefree substances such as water, air or gel.
They also used the process with mayonnaise – creating a five per cent fat version which tastes as good as the full-fat one – and with porridge.
The low-fat chocolate bar, which melts at 32-34 degrees Celsius, was created by bonding water particles with crystals of cocoa butter. A similar technique was used as a way to lower salt content in foods by up to 80 per cent.
While at Unilever, Professor Norton was an inventor on more than 60 granted patents leading to many new and innovative products, including Flora Light and
Chicken Tonight.
Today, Professor Norton holds four EPSRC food-related grants. He also co-leads the
EPSRC Centre for Innovative Manufacturing in Food and the Centre for Sustainable
Energy use in Food Chains.
In 2009, an EPSRCsupported team at the London Centre for Nanotechnology at University College
London (UCL), led by Professor Steve
Bramwell (pictured), discovered ‘magnetricity’ – the magnetic equivalent of electricity.
By proving the existence of currents of atom-sized ‘magnetic charges’, that behave and interact just like electric charges, the
UCL team won the Research Project of the Year prize at the 2010 Times Higher
Education awards.
In the same year, Professor Bramwell was named by The Times on its list of the
100 top UK scientists.
The pioneering research, which revealed an unexpected symmetry between electricity and magnetism, could lead to new and unusual magnetic material properties, with potential applications in technology, such as in ‘magnetic memory’ storage devices or for use in future computer memory.
The research dates back to 1997, when
Steve Bramwell, working with Mark Harris, from the Science and Technology Facilities
Council, discovered the unusual magnetic material ‘spin ice’, drawing attention to certain similarities found within water ice.
In 2010, Professor Bramwell was awarded the Holweck Medal and Prize for pioneering new concepts in the experimental and theoretical study of spin systems.
Two years later he was a co-recipient of the prestigious Europhysics Prize for condensed matter physics, for the prediction and measurement of magnetic monopoles in spin ice.
In 2014, Professor Bramwell led an
EPSRC-supported team who demonstrated the surprising properties of thin films of spin ice.
The team’s research opens up new possibilities for the control and manipulation of magnetricity and magnetic monopoles in spin ice. This could lead to a number of applications; for example, magnetic technology in computer hard disks is often based on thin magnetic films.
In 2010, a carbon calculator software tool developed by chemical engineers led by Professor Adisa Azapagic at The University of Manchester won major awards from the chemical industry, including the Outstanding Achievement in
Chemical and Process Engineering prize at the IChemE 2010 awards.
The team’s CCaLC carbon calculator helps companies measure and reduce their carbon footprint at minimum cost and has been developed in collaboration with a range of industry partners.
Professor Azapagic, who leads the
Sustainable Industrial Systems research group at The University of Manchester, is world-renowned for her work on life cycle sustainability analysis.
In 2011, CCaLC won the GSK Innovation
Award, from the prestigious Chemical
Industries Association.
In 2013, Professor Azapagic became codirector of the newly-formed £7.5 million
Centre for Sustainable Energy Use in Food
Chains, funded by the Research Councils
UK Energy Programme, led by EPSRC. In the same year she was elected a Fellow of the Royal Academy of Engineering.
In 2010, a report by leading economic forecasting consultancy Oxford
Economics, commissioned by EPSRC and the Royal Society of Chemistry, revealed that one in every five pounds in the UK economy is dependent on developments in chemistry research.
Industries reliant on chemistry contributed £258 billion to the UK economy in 2007 – equivalent to
21 per cent of UK GDP – and supported six million jobs, accounting for at least 15 per cent of the UK’s exported goods and attracting significant inward investment.
EPSRC 1994-2014 May 20: Scientists announce they have created a functional synthetic genome
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2011
EPSRC 1994-2014
102

In 2011, UK semiconductor manufacturer,
Plessey, purchased University of Cambridge spin out company, CamGaN, founded by Professor Sir Colin Humphreys to commercialise his ground-breaking research into gallium nitride (GaN), a remarkable man-made material with enormous potential.
Plessey then set up a factory in Plymouth to make millions of GaN LEDs every week, using a process developed at the EPSRCsupported Cambridge Centre for Gallium
Nitride to make a new generation of lowcost, low carbon, long-life LED lighting bulbs which could have a dramatic impact on carbon emissions, among other applications and benefits.
Professor Humphreys says: “If everyone switched to GaN LEDs, we would halve the amount of electricity used in lighting. This would reduce the world’s total electricity consumption by 10 per cent. GaN LEDs also have a longer lifetime and typically only need replacing after 60 years of household use.”
As is often the case, getting to the point where GaN LEDs can be made commercially has largely been about getting costs down. The Cambridge centre’s breakthrough was in working out a way of growing GaN-based semiconductors for
LEDs on silicon wafers, which are much less expensive than the sapphire that was used before. Getting to that point depends upon a profound understanding of how GaN behaves, built up over years of research.
In 1997, an EPSRC grant helped
Professor Humphreys to identify the particular potential of gallium nitride, among a number of other promising semiconductors. He says: “EPSRC should be congratulated on seeing the importance of gallium nitride. In 1997, that wasn’t at all clear.”
In 2000, Professor Humphreys was instrumental in setting up The Cambridge
Centre for Gallium Nitride, which EPSRC has supported ever since, with grants jointly to him and to Professor Phil Dawson at The University of Manchester. The centre works with UK universities and a range of industrial partners to investigate GaN’s unusual properties and develop its myriad possible applications.
In specialist applications, GaN could have a transformative effect. New cancer therapies are being developed which will use GaN devices to show where the edges of tumours are, so that X-rays can be focused on them much more accurately. GaN could also be instrumental in developing new therapies which use protons, rather than X-rays, to zap cancer cells. This work has been initiated by
Professor Bruce Hamilton at The University of Manchester in collaboration with
Professor Humphreys.
Deep ultra-violet GaN light could be used for water purification in the developing world, as it has been shown to kill all known viruses and bacteria. In hospitals, it could be used to wipe out bacteria such as MRSA. Shining a GaN ultra-violet light around a ward could be enough to kill any bugs lurking there.
In the world of computing, gallium nitride could be deployed in the optical computers of tomorrow, which would use photons rather than electrons, making much faster processing speeds possible.
With the extraordinary growth of wi-fi, the current wavelengths it uses will soon be saturated. But GaN could be used to create a kind of ‘li-fi’ – wi-fi provided through an
LED light beam, opening up a new field of complementary wireless networking technology with numerous advantages, including energy efficiency and security.
The term li-fi was coined by its inventor,
Professor Harald Haas, an EPSRCsupported scientist at the University of
Edinburgh and recipient of a 2014 EPSRC
RISE leadership award in recognition of his achievements. Professor Martin Dawson at the University of Strathclyde has an
EPSRC Programme Grant to develop li-fi, in collaboration with Professor Humphreys.
Colin Humphreys says: “We had no idea of some of these applications even 12 months ago. Gallium nitride is a good example of a material where its possible uses can mushroom, once you have a proper understanding of how it behaves.
“For example, just by mimicking sunlight,
GaN LED lights have positive effects. We know that patients on the sunnier side of a ward get better quicker. And schools with higher quality lighting get better results.”
In 2014, the Nobel Prize in Physics was shared by Japanese scientists Isamu
Akasaki, Hiroshi Amano and Shuji
Nakamura for their invention of blue LEDs.
Colin Humphreys and his team are building on this important work. The deal with
Plessey is an integral part of the vision.
Commenting on GaN LEDs’ potential for affordable low-carbon lighting, Professor
Humphreys says: “It’s very important to us that this research will be exploited in the UK. If we had stopped at the research stage, our work would probably have been picked up and commercialised overseas.
“This way, we can create more jobs in a low-employment part of the country and potentially turn Britain into a major centre for better, greener lighting.”
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EPSRC 1994-2014 January 15: Wikipedia, the free internet encyclopedia, turns 10 years old

2011
In 2011, Autonomy
Corporation plc was sold for £7.1 billion to US computing giant Hewlett
FTSE 100 company since
Kraft bought out Cadbury for £13 billion early in 2010.
Packard. It was the largest takeover of a
Founded in 1996 by Dr Mike Lynch to commercialise his EPSRC-funded PhD thesis in mathematical computing at the University of Cambridge, in 16 years
Autonomy became the UK’s biggest pure software company, with nearly 2,000 employees in the UK, and a world leader in allowing computers to harness the full richness of human information.
Over 90 per cent of Fortune 1,000 companies are Autonomy customers and more than two billion people rely on the company’s software every day.
Dr Lynch (pictured), who held a research fellowship in adaptive pattern recognition while at Cambridge, served as CEO of
Autonomy for over 15 years and is widely regarded as Britain’s most successful technology entrepreneur.
He is a Fellow of the Royal Academy of
Engineering, and a scientific adviser to the
UK Prime Minister. He was elected a Fellow of the Royal Society in April 2014.
In 2012, Dr Lynch was inducted into the Digital Hall of Fame, alongside Tim
Berners-Lee, Warren East and Stephen Fry.
In the same year he joined the advisory board of Tech City’s Investment Committee.
He is also an adviser to the Prince’s Trust
Technology Group.
In 2013, Dr Lynch co-founded Invoke
Capital, a technology fund vehicle dedicated to unlocking the potential of
European technology.
In 2013, Invoke made its first investment, in
Darktrace, a cyber-security company based on ground-breaking mathematical research at the University of Cambridge.
In 2011, Dr Sithamparanathan Sabesan and Dr Michael Crisp, from the University of Cambridge, won prizes at the inaugural
ICT Pioneers competition.
The annual competition, which EPSRC coordinates on behalf of sponsor companies such as Microsoft, recognises the most exceptional UK doctoral students in topics related to Information
& Communications Technology (ICT).
The duo went on to receive a Royal
Academy of Engineering (RAE) ERA
Foundation Entrepreneurship Award, together with project partner Boeing, for research into a low-cost location-sensing system that could save airlines and retailers millions of pounds.
The team’s research, which uses a form of radio tagging, was developed as part of the five-year The INtelligent Airport (TINA) project, funded by EPSRC and Boeing.
The TINA project focused on the development of a next-generation advanced wireless network to meet the requirements of future
‘intelligent’ airports for both fixed and mobile appliances.
In 2011, the brightest gamma ray beam ever created – over a thousand billion times more brilliant than the sun – was produced in EPSRCsupported research led by Professor
Dino Jaroszynski at the University of Strathclyde.
The device, which can produce laser pulses lasting a quadrillionth of a second, is smaller and less costly than more conventional sources of gamma rays, a form of X-ray.
Potential uses for the device include applications in medical imaging, radiotherapy and PET scanning.
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EPSRC 1994-2014 March 11: A 9.0-magnitude earthquake and subsequent tsunami hit the east of Japan, killing 15,840 people and leaving another 3,926 missing

In 2011, surgeons in Sweden carried out the world’s first synthetic organ transplant using a windpipe ‘grown’ from the patient’s stem cells.
Without the new windpipe, the patient,
Andemariam Beyene, from Eritrea, whose own windpipe had been blocked by an inoperable tumour the size of a golf ball, would have died. He had been given just two weeks to live – not long enough to find a donor.
The artificial organ was designed and developed by a multidisciplinary team led by Professor Alex Seifalian at University
College London.
EPSRC sponsorship of the project began in 2006, but the windpipe for Andemariam
Beyene was ‘designed’ and grown in just two weeks.
Professor Seifalian’s team worked around the clock to build the polymer windpipe. It was then taken by doctoral student Claire
Crowley, a key member of the development team, to Karolinska University in Sweden where it was ‘seeded’ with the patient’s own cells by a team led by Professor
Paolo Macchiarini.
The full biological trachea was grown in a bioreactor specially designed for the procedure by Harvard Bioscience.
The artificial trachea was successfully transplanted during a 15-hour operation by Professor Macchiarini, who holds an honorary appointment at University College
London, and who worked with Professor
Seifalian on the design and development of the trachea scaffold using a material known as a novel nanocomposite polymer.
Over the past two decades, with funding from EPSRC and the Wellcome Trust, and drawing inspiration from natural structures such as butterfly wings, Professor Seifalian has developed a new generation of strong, flexible biocompatible polymers suitable for use in human patients.
His materials have been used in a range of world-firsts, including transplants of trachea, nose, ear and tear duct. They are also poised to find application in artificial blood vessels, opening up potentially vast markets.
In 2013, Claire Crowley visited Andemariam
Beyene in Iceland, where he was alive and well and in his final year as a PhD geology student at the national university.
In 2014, Professor Seifalian (pictured, with
Claire Crowley) began work on two threeyear EPSRC-supported projects in the field of regenerative medicine, in partnership with Pharmidex Pharmaceutical Services.
One project in particular, in partnership with Biomer Technology Ltd, includes building a custom-made 3D bio-printer with multi-printing heads and an environmental chamber which can print
‘live’ tubular organs with trachea as an exemplar. This project has paved the way to printing a range of artificial organs to meet individual patient needs.
In 2011, using a ray of light the width of a human hair, a team of researchers at the
University of
St Andrews developed a new method for testing whether another. By analysing the collection of light scattered from the whisky, the researchers were able to diagnose the sample.
Using this sample, the team were able to investigate and discriminate single malt
Scotch whiskies based on brand, age and even which cask had been used.
of making stainless steel surfaces become resistant to bacteria, and also stronger.
By introducing silver or copper into the steel surface (rather than coating it on to the surface), the researchers developed an innovative technique that not only kills bacteria but also makes the surface very hard and resistant to wear and tear during cleaning.
a whisky is genuine.
The chip used in the study was originally employed to detect bio-analytes in biomedical studies.
Bacteria resistant surfaces could be used in hospitals to prevent the spread of superbug infections on stainless steel surfaces, as well as for medical equipment, for example, instruments and implants.
The method can work out the brand, age and even which cask was used to create a single malt, from a sample no bigger than a teardrop.
The patented research, subsequently presented to the drinks industry, which loses millions annually to counterfeit producers, was carried out by physicists Praveen Ashok,
Kishan Dholakia and Bavishna Praveen.
The project involved researchers placing a tiny amount of whisky on a transparent plastic chip no bigger than a credit card.
Using optical fibres the width of a human hair, the whisky sample is illuminated by light using one fibre, and collected by
EPSRC 1994-2014
In 2011, materials scientists at the
University of Birmingham, led by Professor
Hanshan Dong, devised an innovative way
The technology developed by Professor
Dong and his team could also be adapted for use in the food industry and in domestic and professional kitchens.
In 2013, Professor Dong was awarded a £230,000 grant from the Commission of the European Communities to develop innovative plasma surface alloying technologies.
Today, Professor Dong is director of the
EPSRC Centre for Doctoral Training in
Innovative Metal Processing based at the
University of Birmingham.
September 22: CERN scientists erroneously announce their discovery of neutrinos breaking the speed of light
105

2011
In 2011, EPSRC-sponsored researchers from the University of Oxford equipped a modified Bowler Wildcat off-road vehicle
(pictured) with technology to help it ‘see’ the world around it, and enable it to drive itself, without any human intervention. One day this technology could help cut down on road accidents and traffic congestion, which cost the UK economy more than £4.3 billion a year, or £491 per car-commuting household.
The project is part of research at the university’s Mobile Robotics Group (MRG) coled by Professor Paul Newman, an EPSRC
Leadership Fellow, and Professor Ingmar
Posner, who say the low-cost technology enabling the vehicle to drive itself could one day be a feature on all cars.
The research group use the mathematics of probability and estimation to enable computers in cars and robots to interpret data from cameras, radars and lasers, aerial photos and road plans.
The group have been at the cutting edge of research into infrastructure-free navigation
(i.e. navigation without GPS) for over a decade, and are acknowledged leaders
EPSRC 1994-2014 in this area. Paul Newman puts things succinctly: “If it moves, mobile autonomy has a role to play.”
The team’s innovative navigation software can be applied to surveying, mining, warehousing and agriculture, and it has already been licensed for use on the
European Space Agency’s ExoMARS project.
MRG’s initial research into autonomous vehicles, co-sponsored by EPSRC Strategic
Partner BAE Systems, used a Bowler
Wildcat, based on a Land Rover Defender.
Now, working with Japanese manufacturer
Nissan, the team have installed their latest technology in a Nissan Leaf electric car, which gives a glimpse of what driving an
‘autonomous’ car of the future might be like.
The car’s low-cost in-car navigation system uses 3D laser mapping, and can recognise its surroundings using small cameras and lasers discreetly built into the vehicle’s body and linked to a computer in the boot.
Unlike the automated technology that has already found its way into some production cars, the system does not rely on GPS for
October 31: The world population reaches seven billion inhabitants according to the United Nations the cars to find their way. The researchers explain that such systems cannot provide the coverage, precision and reliability autonomous cars need to safely navigate.
Crucially, GPS also fails to tell a robotic car anything about its surroundings.
The technology is controlled from an iPad on the dashboard, and at any time a tap on the brake pedal returns control to the human driver.
In 2014, Professors Newman and Posner formed a spin out company, Oxbotica, to commercialise their research, and to exploit the Mobile Robotics Group’s suite of intellectual property and know-how developed over a decade of research. In the same year, Professor Newman was awarded a Fellowship of the Royal Academy of Engineering.
In 2014, Innovate UK (formerly known as the Technology Strategy Board) invested £250,000 in Oxbotica to develop a production-feasible prototype of a low cost, infrastructure free (without GPS),
3D imaging device.
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In 2011, an early warning system to warn of landslides, developed by an
EPSRC-supported team at Loughborough
University led by Professor Neil Dixon, won
The Engineer magazine’s Civil Engineering
Award at its annual awards.
Thought to be the first of its kind in the world, the Slope ALARMS detection system, developed through a collaboration between
Loughborough University, Geotechnical
Observations and the British Geological
Survey, is a network of sensors buried across the hillside or embankment that presents a risk of collapse. The sensors, acting as microphones in the subsoil, record the acoustic activity of the soil across the slope and each transmits a signal to a central computer for analysis.
As well as the life-saving implications for countries prone to disastrous landslides, the technique can be used in monitoring the condition of potentially unstable slopes built to support transport infrastructure, such as rail and road embankments, in developed countries such as the UK.
In 2012, Professor Neil Dixon received a follow-on EPSRC research grant to develop a revised lower power design of the Slope
ALARMS sensor.
In 2013, Professor Dixon began work on a multidisciplinary, multi-partner EPSRCfunded project investigating the sustainable management of embankment slopes.
The project is led by Professor Stephanie
Glendenning from Newcastle University, a key member of the Assessing the
Underworld project (see pages 62-63).
In 2011, to showcase ground-breaking 3D printing technology, a team of scientists at the University of Exeter, led by Dr Liang Hao, unveiled the world’s first chocolate printer using know-how that could revolutionise the retail industry.
An EPSRC-produced YouTube video of the printer in action has since received
650,000 hits.
Dr Hao and his team were the first to develop a way of applying 3D printing to chocolate, which is a challenging material to work with because it requires accurate control of viscosity and temperature conditions.
Dr Hao says: “In future this kind of technology will allow people to produce and design many other products such as jewellery or household goods. Eventually we may see many mass-produced products replaced by unique designs created by the customer. We also envisage consumers owning their own 3D printers.”
In 2012, Dr Liang Hao founded Choc Edge
Ltd, to develop and sell its unique 3D chocolate printer developed under the research project.
EPSRC 1994-2014
In 2011, a study by researchers at the
University of Bristol used social media, such as Facebook and microblogging services like Twitter, to track events or phenomena such as flu outbreaks and rainfall rates.
The research geo-tagged user posts on the microblogging service of Twitter to investigate two scenarios: levels of rainfall in a given location and time using the content of tweets; and regional flu-like illness rates from tweets to find out if an epidemic was emerging.
Professor Nello Cristianini, who led the research, says: “Twitter, in particular, encourages its 200 million users worldwide to make their posts publicly available as well as tagged with the user’s location.
“Our research has demonstrated a method, by using the content of Twitter, to track an event when it occurs and its scale.”
Interviewed in 2012, Dr Hao said: ”The initial worldwide interest in creative and bespoke
3D chocolate products was enormous… By next Easter, consumers will be able to order their own, personalised Easter eggs along with other chocolate gifts.”
In 2013, the company launched Choc
Creator V2, a more sophisticated and efficient design, and created a chocolate printer hub to develop a community of people engaged in 3D chocolate printing.
The technology featured on popular TV show
The Gadget Man, hosted by Stephen Fry, who held a high-tech dinner party for friends.
In 2014, Choc Creator V2 was highly rated in a special Christmas party edition of Channel
5’s The Gadget Show.
April 29: An estimated two billion people watch the wedding of Prince William, Duke of Cambridge and Catherine Middleton at Westminster Abbey
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2012
In 2012, Dr Simon Colton, an
EPSRC Leadership Fellow based at Imperial College
London, was nominated for a prestigious World
Technology Arts Award for his work with The Painting Fool, a computer programme he developed that paints original artwork inspired by what it sees. The pictures in this article are examples of the Painting Fool’s handiwork.
Dr Colton (pictured), an Artificial
Intelligence researcher specialising in questions of computational creativity, who today leads Goldsmith University’s
Computational Creativity Group, has programmed the Painting Fool to recognise human emotions and create original paintings, in a variety of styles.
The hope is that one day it will be taken seriously as an artist in its own right.
Dr Colton’s work has been covered widely by the UK and international media, both in print and on television, including BBC’s
Horizon and newspapers such as the
Daily Mail, the Daily Mirror, El Pais and
El Mundo.
The Observer carried a wide-ranging feature on the Painting Fool, whose work has been exhibited in five group exhibitions in London, Brussels, Paris and Lisbon.
In 2013, The Painting Fool turned his creative talents to poetry, drawing his inspiration from news stories.
EPSRC 1994-2014 February 6: Queen Elizabeth II marks her 60th anniversary as British monarch
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EPSRC 1994-2014 February 28: Discovery of the largest prehistoric penguin, Kairuku grebneffi, at nearly 5ft tall
109

2012
In 2012, pioneering research by
EPSRC-sponsored scientists revived the fortunes of the
MASER (Microwave
Amplification
Stimulated Emission of Radiation), a cousin of the ubiquitous laser, first developed nearly
60 years ago.
Despite predating the laser by five years, the maser has had little technological impact – primarily because it was inconvenient to use.
Masers, which use concentrated beams of microwaves rather than intense beams of light, require high magnetic fields and subzero conditions to work. Hence for so long they were left out in the cold, only able to operate at temperatures close to absolute zero, minus 273 degrees Celsius – the same temperature as interstellar space.
Masers are used only in very specialised applications such as atomic clocks and as amplifiers in radiofrequency telescopes, but the results can be spectacular. For example, masers were responsible for the stunning images of the solar system taken by the Voyager spacecraft.
The researchers, from Imperial College
London, led by Professor Neil Alford
(pictured), and Dr Mark Oxborrow, formerly of the National Physical Laboratory (NPL) and now at Imperial, demonstrated new technology that makes it possible for the maser to function at room temperature, and without the need for an external magnet. The breakthrough meant the cost to manufacture and operate masers could be dramatically reduced. This paves the way for their widespread adoption.
Potential applications for the maser include more sensitive medical scanners; chemical sensors for remotely detecting explosives; advanced quantum computer components; and better radio astronomy devices for potentially detecting life on other planets.
Professor Alford says: “When lasers were invented, no one knew exactly how they would be used; yet they are now ubiquitous.
There’s a long way to go before the maser reaches that level, but our breakthrough does mean this technology can start becoming more useful.”
The research was funded by EPSRC and, at NPL, through the UK’s National
Measurement Office, and builds on over
20 years of consistently innovative EPSRCsupported materials science research by
Professor Alford.
Professor Alford says: “The work really started with my first EPSRC grant, in 1995, enabling me to carry out research into low microwave loss dielectrics. This was followed by a small feasibility study, also funded by EPSRC, which ultimately led to the maser.”
Over 20 years Professor Alford has been supported by more than 40 EPSRC grants, including consecutive Platform Grants, from 2004-2009, to investigate microwave dielectric materials, and a six-year
Programme Grant in 2009 to develop nanostructured materials for energy efficient refrigeration, energy harvesting and production of hydrogen from water.
In 2005, among notable achievements related to his microwave-based research,
Professor Alford led the development of technology that uses heat delivered by microwaves to destroy liver tumours.
The EPSRC-funded research team, from
London South Bank University and the
University of Bath, found that by heating cancer cells to around 80 degrees Celsius
(much higher than previous microwave treatments) a large region of necrosis – cell death – can be generated.
In 2007, Professor Alford was awarded a
Royal Academy of Engineering Fellowship; in 2010, he was awarded Fellowship of the
Royal Society of Chemistry; and in 2013 received an MBE.
In 2013, Professor Alford received a followon EPSRC grant to construct a maser that can work at room temperature and in the Earth’s magnetic field. The research team are exploring new materials that will miniaturise the maser, which will also require very low power input to achieve the threshold required for masing.
As director of materials at Imperial,
Professor Alford’s knowledge is sought after, and in 2013 he advised Apple on suitable screen materials for its iPhone 6 mobile phone.
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EPSRC 1994-2014 April 10: Apple claims a value of US$600 billion, making it the largest company by market capitalisation in the world

EPSRC 1994-2014 July 27–August: The 2012 Summer Olympics are held in London
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2012
In 2012, The
Engineering Doctorate
(EngD), EPSRC’s innovative doctoral training programme where students spend the majority of their time working in industry, turned 20 years old.
British Steel, which became Corus Group, was later sold to Tata Steel, one of EPSRC’s
Strategic Partners.
Interviewed in 2002, Martin Brunnock said: “The benefit of still being involved in the scheme is that I can help mentor and encourage new research engineers with my previous experience. It’s also a fantastic opportunity to be involved with new research projects which are generally at the forefront of technology.”
In 2012, EPSRC co-funded the new COATED
EngD centre at Swansea University, providing funding to recruit 21 EngD students between 2012 and 2014.
The range of research projects at COATED includes boron steel processing, car chassis fatigue performance, solar cell development, life cycle analysis and recycling. The initial investment was followed two years later by further EPSRC funding for the COATED 2 initiative, which will create 40 research doctorate posts at
Swansea University, focusing on generating energy through new coatings for materials.
In 2013/14, the Swansea Tata plant received over 200 major international orders for its lightweight armour steel, Pavise, formerly known as super-bainite, the brainchild of Professor Harry Bhadeshia at the University of Cambridge. Professor
Bhadeshia’s research has been supported by EPSRC and its predecessor, the Science and Engineering Research Council (SERC) for over 20 years. His work with British
Steel led to the unique alloys used to make the rails for the Channel Tunnel, Europe’s busiest rail link.
The EngD is a doctoral level qualification that involves a taught component and a large, four-year research project defined by industry.
In addition to developing a new generation of industry-savvy doctoral students, the relationship between university and industrial sponsor provides a level of access to industry not normally available to academics; it also enables companies, sectors and policymakers to be guided by the results of the research.
On receiving his Engineering Doctorate at Swansea University in 1997, Dr Martin
Brunnock (pictured) joined British Steel, the company which sponsored his EngD.
A year later he was supervising a new crop of five research engineers from the EngD scheme. He has since risen through the company’s ranks.
EPSRC 1994-2014
Pavise, developed by Tata Steel in partnership with the University of
Cambridge and the MoD, is twice as strong as the current product on the market.
Martin Brunnock says: “The technical expertise behind this material is nothing short of brilliant.”
Today, Martin Brunnock is Technical
Director of Tata Steel’s Strip Products UK division based in Port Talbot and Llanwern,
Wales, one of the largest in Europe, producing five million tonnes of liquid steel per annum, and with a turnover of over £2 billion.
The powertrain picture illustrating this story is an award-winning photograph by former EngD Steel Technology Research
Engineer Ed Carter, who designed, drew and rendered up the image himself.
July 30-31: In the worst power outage in world history, the 2012 India blackouts leave 620 million people without power
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In 2012, EPSRC invested £60 million in
UK universities to help the country’s most pioneering scientists and engineers create successful businesses from their research, improve industrial collaboration and foster greater entrepreneurship.
The three-year initiative awarded ‘Impact
Acceleration Accounts’ (IAAs) ranging from £600,000 to £6 million to over
30 universities across the UK.
The funding helps support the universities’ best scientists and engineers to build even stronger collaborations with industry, bridge the gap between the lab and the marketplace and help them become better entrepreneurs.
IAAs replaced EPSRC’s highly successful
Knowledge Transfer Account (KTA) and
Knowledge Transfer Secondment (KTS) schemes, which saw a step-change in knowledge exchange and collaboration between universities, business and other parties and generated significant material contributions from business.
To exploit EPSRC’s research and training portfolio, universities employ knowledge transfer experts. When a university and an SME identify an opportunity to work together, the IAA’s flexibility enables the university to react very quickly with the company and start the work right away, by drawing on IAA funding dedicated to them.
A recent example of impact arising from
IAA funding is a research project at the
University of Bath.
The team used their Impact Acceleration
Account to accelerate the development of technology that could help monitor blood glucose control in diabetes patients and an array of age-related conditions, including Alzheimer’s.
Working with leading medical device company, glySure Ltd, the Bath research team demonstrated a new technique that could be used in blood tests to detect levels of ‘glycated proteins’ in blood and tissue samples.
The team’s method allows scientists to identify signature profiles of glycated proteins linked to particular diabetic conditions. In the future the same method could be applied to new technologies to screen for diseases like Alzheimer’s.
In 2014, at the end of their first year there were 457 IAA projects, 152 secondments,
291 new company partners and 38 joint academic publications.
Contribution from business and other partners was £22 million, in addition to the
£20 million invested by EPSRC.
In 2012, a collaboration between the
University of Sheffield and London College of Fashion, with initial support from EPSRC, led to a revolutionary liquid laundry additive to help make the clothes we wear purify the air as we move around in them.
The additive contains microscopic pollution-eating particles, and clothes need to be washed in it just once, as the nanoparticles of titanium dioxide grip onto fabrics very tightly.
When the particles come into contact with nitrogen oxides in the air, they react with these pollutants and oxidise them in the fabric.
The nitrogen oxides treated in this way are odourless, colourless, and pose no pollution hazard. The method removes
5g of nitrogen oxides every day – equivalent to the daily amount produced by the average family car.
Project co-leader, Professor Tony Ryan
OBE, of the University of Sheffield, says:
“If thousands of people in a typical town like Sheffield washed their clothes in the additive, there would be no pollution problem caused by nitrogen oxides at all.”
EPSRC 1994-2014 May 5: Japan shuts down its nuclear reactors, leaving the country without nuclear power for the first time since 1970
In 2012, EPSRC spearheaded a
£40 million investment under the
RCUK Energy Programme, which is led by EPSRC. The investment included
£20 million jointly with the National
Natural Science Foundation of China in
‘smart’ power grids, which manage the supply and demand of power through the national distribution network.
EPSRC also led one of the biggest
Research Council low carbon energy investments; contributing £26 million in five new End Use Energy Demand research centres. The centres are investigating the complexities of energy use across society and explore how energy can be both saved and used more efficiently. The investment included a further £13 million from industrial partners.
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2012
The initial project, funded under the During discharge, the system can
EPSRC-led RCUK Energy Programme, simultaneously convert low grade was an international academic/industry waste heat into power, further collaboration. The Leeds team joined increasing the overall efficiency by forces with commercial partner, Highview producing additional power.
Power Storage, the UK-based developer of
The system uses established technology, large-scale long duration liquid air energy can be built anywhere, and can easily storage (LAES) systems, and Chinese be scaled up. A pilot facility near Slough colleagues to co-design and lab test a
(pictured) began providing electricity to the novel cryogenic energy storage system that
National Grid in April 2010, and can meet stores off-peak energy, using liquefied air the power needs of several hundred houses
In 2012, energy storage research as the storage medium. for up to eight hours.
co-developed by EPSRC-supported Ambient air is drawn from the environment researchers at the University of Leeds,
Using pioneering combined heat and power where it is cleaned, compressed and systems such as this, one day homes could led by Professor Yulong Ding, scientists liquefied at sub-zero temperatures; at the Chinese Academy of Science, and have their own domestic electrical energy
700 litres of ambient air become one litre storage system, providing heating, power, commercial partners led to the creation of liquid air. The liquid air can be stored in of a joint EPSRC-supported international refrigeration and air conditioning.
an insulated storage tank at low pressure
In 2014, Professor Yulong Ding joined the research institute with over 45 researchers for extended periods of time without working on more than 20 projects.
University of Birmingham as the newly significant losses. appointed Highview Power Storage/Royal
The formation of the institute, which When power is required, liquid air is drawn focuses on next-generation energy storage
Academy of Engineering Research Chair from the tanks, pumped to high pressure in Energy Storage.
systems, followed the project’s runaway and heated. This process produces a highsuccess at The Engineer magazine’s 2011
Technology and Innovation Awards, winning
To support Professor Ding in his work, pressure gas, which is then used to spin a turbine which drives the generator to Highview is relocating its 350kW/2.5MWh both its category and the grand prize.
LAES pilot plant to Birmingham.
produce electricity.
In 2012, EPSRC invested £16 million in
22 university-based research projects to develop smart robots and autonomous systems such as unmanned aircraft – considered vital to many areas of UK industry, from oil and gas exploration to advanced manufacturing.
Led by EPSRC, the project involves an eight-strong group of partners, including
BAE Systems, Sellafield Ltd and the UK
Space Agency, investing over £4 million in support.
The projects include ‘nursebots’ that assist patients in hospitals; safe ways of monitoring in dangerous environments
EPSRC 1994-2014 such as deep sea installations and nuclear power plants; and aerial vehicles that can monitor national borders or detect pollution.
August 6: Curiosity, the Mars Science Laboratory mission’s rover, successfully lands on Mars
In 2012, EPSRC co-invested with other research councils £25 million in the fast emerging discipline of regenerative medicine. A key part of the investment, which will produce a set of research priorities for UK regenerative medicine research and development, is a new cross-research council UK Regenerative
Medicine Platform, to work in close partnership with the £50 million Innovate
UK Cell Therapy Catapult Centre.
Co-investors are: the Medical Research
Council, Biotechnology and Biological
Sciences Research Council, Economic and
Social Research Council and Innovate UK.
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Picture courtesy Agnese Sanvito
In 2012, a team of EPSRC-sponsored engineers at Loughborough University, co-led by Dr Richard Buswell and Professor
Simon Austin, developed an innovative 3D printing technique to create customised panels for large-scale buildings. An example of their work is pictured above.
The process was developed at the EPSRC
Innovative Manufacturing and Construction
Research Centre (IMCRC) at Loughborough
(see page 36).
The team have since developed 3D concrete printers fitted to a gantry and a robotic arm.
The printer can make things which cannot be manufactured by conventional processes such as complex structural components, curved cladding panels and other architectural features.
Dr Buswell says: “Freeform gives architects and builders the creative freedom to design and build hitherto unfeasible concrete
‘components’, such as curved panels, while reducing the high cost penalties associated with traditional methods.”
With further funding from EPSRC, the team are collaborating with industry partners to commercialise the process, which could capture a significant share of the US$450 billion global concrete and cement market.
In 2012, EPSRC-supported scientists developed 3D computer software that can create and test automation systems before they’re even built, potentially saving manufacturers millions of pounds while increasing their competitiveness.
The software, which builds up a virtual representation of the automated system, allowing engineers to get their fingers dirty in 3D, was developed by a team at the
EPSRC Innovative Manufacturing and
Construction Research Centre (IMCRC) at Loughborough University.
The tool is aimed at helping manufacturers save money, increase efficiency, improve prototype safety and accelerate the process of getting their products to market.
The research focused on applications in automotive engine assembly but can potentially be used across the manufacturing sector. Commercialisation of the software tools and services developed by the project has begun through the licensing of the software by the university to project partner
Fully Distributed Systems Ltd.
The project, known as Business Driven
Automation, was led by Professor Robert
Harrison. He says: “Conventional automation systems are slow and complex to service, reconfigure and integrate. The software we’ve developed gives a quick, accurate, virtual 3D prototype view of assembly machine behaviour before the machines are physically built.
“We aim to make these tools much easier and faster to develop and use, and we want to see them used throughout the machine lifecycle, not just at initial build.”
In 2012, an EPSRC-sponsored team from the University of Lincoln, led by Professor
Paul Stewart, showed how the aircraft of tomorrow could self-contribute to their power needs by harnessing energy from the wheel rotation of their landing gear on the tarmac.
In 2012, a team of EPSRC-funded scientists at Imperial College London, led by Professor Molly Stevens, developed a prototype ultra-sensitive sensor that would enable doctors to detect the early stages of diseases and viruses with the naked eye. The visual sensor technology is
EPSRC 1994-2014
The feasibility project showed how the energy produced by a plane’s braking system during landing – currently wasted as heat produced by friction in the aircraft’s disc brakes – would be captured and converted into electricity by motorgenerators built into the landing gear.
10 times more sensitive than the current gold standard methods for measuring biomarkers, which are used to indicate the onset of diseases such as prostate cancer and infection by viruses including HIV.
The sensor could benefit countries where sophisticated detection equipment is scarce, enabling cheaper and simpler detection and treatments for patients.
September 12: Apple unveils its iPhone 5 and iOS 6
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2013
£39 MILLION FOR UK ENERGY CENTRES
In 2013, EPSRC co-funded one of the biggest Research Council investments to support UK energy efficiency policy, reduce carbon use and cut greenhouse gas emissions.
£45 MILLION FOR MANUFACTURING
In 2013, EPSRC invested £45 million to develop innovative new manufacturing technologies, techniques and systems.
The investment includes: strengthen research in the areas of
Robotics and Autonomous Systems,
Advanced Materials and Grid-scale
Energy Storage.
Five new End Use Energy Demand research centres received a total of
£39 million from EPSRC, which leads the
Research Councils UK Energy Programme, the Economic and Social Research Council
(ESRC), and industrial partners, which contributed £13 million.
• £21 million for four new Centres for
Innovative Manufacturing
• £12.2 million towards six flexible manufacturing projects
• Six information & communications technology (ICT) research projects for
UK manufacturing competitiveness
The research, involving 20 UK universities, will underpin key sectors of the
UK economy, including automotive, manufacturing, aerospace, energy and healthcare.
£39.4 million will be invested in robotics and autonomous systems (£25 million from EPSRC; £8.4 million from higher education institutions; and £6 million from industrial partners) The funding enables the research centres to look into the complexities of energy use across society and explore how energy can be both saved and used more efficiently.
£32 MILLION FOR INTERDISCIPLINARY
RESEARCH COLLABORATIONS
In 2013, EPSRC invested £32 million in three major Interdisciplinary Research
Collaborations (IRCs) that could help revolutionise healthcare. The research focuses on developing new information
& communications technology (ICT) applications and systems to tackle increasingly pressing problems, such as an ageing population and severely overstretched hospitals.
The investment, spanning 10 universities and 18 industry and academic partners, brings together multidisciplinary researchers from areas including pathology and electrical engineering to develop technologies such as sensors in patients’ clothing that monitor their condition, and smartphones that can diagnose and track the spread of infectious disease.
EPSRC 1994-2014
The projects demonstrate the collaborative nature of manufacturing research and bring together nine universities and over
70 manufacturing partners.
£47 MILLION FOR ENGINEERING
In 2013, EPSRC invested £47 million in new engineering projects to tackle global challenges such as climate change; improving healthcare; and meeting basic needs, including access to clean water.
The investment included £25 million in five frontier engineering projects in areas such as nature inspired engineering; synthetic biology applications to water; individualised multi-scale simulation; and simulation of open engineered biological systems.
EPSRC invested a further £20 million in large Programme Grants to four UK universities, focusing on resilience, health and technology and growth.
ADDITIONAL INVESTMENTS
In 2013, EPSRC invested £85 million in a range of projects to support and
£47.2 million will be invested in advanced materials (£30 million from EPSRC with additional funding of £11.7 million from higher education institutions and
£5.5 million from industrial partners)
£45.6 million will be invested in grid-scale energy storage (£30 million from EPSRC with additional funding of £9.8 million from higher education institutions and
£5.8 million from industrial partners)
£10 MILLION WITH JLR
In 2013, EPSRC and Jaguar Land Rover co-invested £10 million in the first phase of a 20-year strategic project led by four leading UK universities to advance the UK’s role in developing virtual simulation technologies.
The investment will give engineers a more realistic perception of what a design might achieve, as well as access to more powerful computers as part of a package that could put the UK at the leading edge of virtual simulation globally.
January 17: Japan unveils plans to build the world’s largest wind farm near the Fukushima Daiichi nuclear power plant
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In 2013, an unmanned aerial drone which monitors radiation levels after a nuclear incident was developed by an EPSRCsupported University of Bristol team.
The drone was inspired in response to the
Fukushima nuclear disaster in 2011 after helicopter pilots risked radiation exposure as they mapped the disaster area.
Oliver Payton, James MacFarlane and John
Fadoulis, from the University of Bristol’s
Interface Analysis Centre, developed the remote controlled Advanced Airborne
Radiation Monitoring (AARM) system, with funding from EPSRC and
Sellafield Ltd.
Tom Scott, project lead and
Director of the Interface
Analysis Centre in the
University’s School of
Physics, says: “By using lightweight and low-cost unmanned aerial vehicles, we can immediately and remotely determine the spread and intensity of radiation following any such event.
“The systems have sufficient inbuilt intelligence for deployment following an incident and are effectively disposable if they become contaminated.”
The drone uses laser distancing to enable safe flight in narrow spaces. It can map the
3D environment with millimetre precision and also capture high resolution images.
The team are also developing thermal imaging, gas and acoustic sensors for the drone.
The on-board microcomputer integrates multiple sensor streams to provide radiation mapping with excellent spatial resolution and sensitivity.
The software is controlled from a laptop, and attachments can be plugged in according to the task in hand.
The drone’s rotor arms fold back so that the system can be fitted into a standard travel case, making it easy to take on a plane and rapidly deploy.
In 2014, the drone was used to map radiation surrounding the Fukushima site to help the clean-up before people can return to their homes.
In April 2014, the AARM team, led by
Tom Scott, provided Sellafield’s first ever drone survey of any type, demonstrating the team’s radiation mapping technology combined with aerial photography.
James Moore, who leads on UAV technologies at Sellafield, says: “This system, to the best of our knowledge, represents the current state of the art for radiation-mapping UAS systems.”
In 2014, the Royal Academy of Engineering awarded James MacFarlane and Oliver
Payton the ERA Foundation Entrepreneurs
Award. The prize is helping them develop the drone commercially for use in disasters, routine radiation monitoring at nuclear sites and mining operations. Spin out company Imitec has been set up to take this forward.
In 2013, the universities of Salford and
Lancaster won a Modeshift national transport award for a smartphone app developed for parents to keep track of their child’s walking bus (a group of children
EPSRC 1994-2014 walking to school with one or two adults) during the school run.
Salford psychologists
Dr Sarah Norgate and
Nikki Jones teamed up with researchers Chris
Winstanley, Mike Harding and Professor Nigel
Davies from Lancaster
University to develop the app. Dr Norgate says:
“Walking school buses are an effective way to promote children’s independent mobility and road sense. With this new application, parents can track the safe arrival of the walking school bus at the school gates.”
Families at Westwood Park Primary School in Eccles trialled the app with one of the
February 5: The House of Commons votes in favour of same-sex marriage walking school bus coordinators, Trish
Kiernan (pictured). Head Teacher Sara
Walker says: “Children are motivated to see the arrival of the walking school bus on the screen, and to join other pupils on the school run.” Mark Mountcastle, Head
Teacher at St Hugh of Lincoln RC Primary in Stretford, which also helped to trial the app, agrees. He says: “It’s a brilliant way to encourage the children not only to walk to school but to use technology in a creative and practical way.”
The award-winning project is funded by the
RCUK Digital Economy programme, led by EPSRC, and is part of the Sixth Sense
Transport initiative between the University of Salford, Lancaster University, the
University of Southampton, the University of Edinburgh and Bournemouth University to develop apps that will encourage more sustainable travel options.
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2013 acoustics to quickly locate blockages and structural defects, and to determine the pipe length and the serviceability of the pipe, won a multitude of awards.
Sound affects: SewerBatt™ technology being demonstrated in Singapore for PUB, the national water company .
In 2013, Acoustic Sensing Technology Ltd, a spin out company from the University of
Sheffield, was formed to commercialise the EPSRC-supported research of
Professors Kirill Horoshenkov and
Simon Tait, who previously worked at the University of Bradford.
In less than 12 months, the company’s first product, the SewerBatt™, which uses
The technology builds on 15 years of
EPSRC-supported work by Professors
Horoshenkov and
Tait at the universities of Bradford and
Sheffield.
Since its launch in
2013, SewerBatt™, the idea for which was conceived by water industry pioneer
Richard Long, has received glowing praise from industry experts, leading Piers Clarke,
Thames Water’s Commercial Director, to describe it as “a phenomenal technology”.
In 2014, SewerBatts were adopted into
Yorkshire Water’s five-year plan, and the company began installing them in areas vulnerable to sewer flooding.
In 2013, a new technique that uses
MRI scans to detect cancer by imaging tumours’ consumption of sugar was unveiled by EPSRC-supported scientists led by Dr Simon Walker-Samuel at
University College London.
The breakthrough could provide a safer and simpler alternative to standard radioactive techniques and enable radiologists to image tumours in greater detail.
The new technique, called ‘glucose chemical exchange saturation transfer’
(glucoCEST), is based on the fact that tumours consume much more glucose (a type of sugar) than normal, healthy tissues in order to sustain their growth.
The researchers found that sensitising an
MRI scanner to glucose uptake caused tumours to appear as bright images on
MRI scans of mice.
In the future, patients could potentially be scanned in local hospitals, rather than having to be referred to specialist medical centres.
In 2013, an academic/industry partnership supported by EPSRC led to a biofuel production process that also yields a viable poultry feedstuff as a ‘by-product’.
With around 80 billion litres of bioethanol fuel produced each year from fermented cereals, the team’s findings are by no means chicken feed.
The project was borne out of the vision of biofuels pioneer, Dr Pete Williams of AB
Agri, the agricultural division of Associated
British Foods. Williams was convinced valuable material was being overlooked when cereals were fermented to make bioethanol.
The team showed that Yeast Protein
Concentrate (YPC) made during the fermentation process could be a costcompetitive alternative to soya-based
EPSRC 1994-2014 protein and other feeds given to chickens bred for meat production.
With project supervisor Dr Emily Burton, of
Nottingham Trent University, Dr Williams secured funding for Dawn Scholey, a doctoral student at Nottingham, to join the team under an EPSRC CASE studentship.
By examining the composition of the newly isolated and patented YPC, Dawn showed it could be both separated from the cereal matter and was a viable alternative nutrient readily digested by chickens.
A project at a US bioethanol facility is already demonstrating the performance of the process at factory scale.
The new process separates the dried distiller’s grains (DDGs) into three fractions: fibre, a watery syrup and YPC, allowing annual global production of almost three million tonnes of supplementary highquality protein alongside current levels of bioethanol produced.
Dr Burton says:
“One concern with bioethanol is the perception it will compete with food crops for limited farmland.
Our new work shows how the two can live side by side.”
Dr Pete Williams says: “We couldn’t have got this development started without the
EPSRC CASE studentship that allowed us to establish the proof of concept, and to confirm the value-creation potential of our innovative separation process.”
March 13: Cardinal Jorge Mario Bergoglio of Argentina is elected the 266th Pope, whereupon he takes the name Francis
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Unlike airport scanners, the device
(pictured) does not produce an image of the subject but only analyses radar signals reflected from the person.
The machines work at a distance of up to
25 metres using low power millimetrewave radar signals that reflect off a weapon and back to the scanner, but without compromising people’s privacy or health.
In 2013, a team of scientists at Manchester
Metropolitan University unveiled a hightech radar scanner which automatically detects hidden bombs and guns on people.
The scanner works in real time using radar waves and complex computer programs, and is destined to revolutionise security at airports, shopping centres, stadia and transport hubs.
The technology is designed to rapidly scan individuals in a crowd as they pass through areas such as public spaces, gates or entrances and instantly alert officials as soon as a threat is detected.
The portable, battery-powered devices include a handheld system for mobile use in the street and a larger, extended range static version suitable for checkpoints or vehicle mounting.
The prototypes are currently being turned into commercial versions ready for security services around the world with customers already lined up to test the technology.
Project Leader, Professor Nick Bowring, started to develop the system in 2004 after initial funding from EPSRC, followed by the Metropolitan Police and the Home
Office. He says: “The technology is a combination of a radar system and an
AI-based computer system. It would have been unthinkable to make it just five years ago because the computing power and hardware were just not there.”
In 2013, Nigel Shadbolt, from the University of Southampton, Professor of Artificial
Intelligence and one of the world’s leading experts in web science, was knighted in the
Queen’s Birthday Honours List for services to science and engineering.
Professor Shadbolt’s research has taken in a broad range of topics, from natural language understanding and robotics to computational neuroscience and memory through to the Semantic Web and linked data.
Professor Shadbolt, who has held over
20 EPSRC grants over more than 25 years, is founding director of the Open Data
Institute, with World Wide Web pioneer
Professor Sir Tim Berners-Lee.
From 2000-2007, Professor Shadbolt led and directed the widely influential
EPSRC-funded Advanced Knowledge
Technologies Interdisciplinary Research
Collaboration (IRC).
thumb-type 34 per cent faster on tablets than when using a QWERTY keyboard.
The IRC produced some of the most important Semantic Web research of the period, such as how diverse information could be harvested and integrated and how semantics could help computer systems recommend content.
Dr Kristensson’s EPSRCsupported research at
St Andrews includes the development of technology that could lead to much faster and easier synthetic voice systems, such as that used by Stephen Hawking.
In 2009, the Prime Minister appointed
Professors Shadbolt and Berners-Lee as
Information Advisers to transform access to Public Sector Information. The work arising from this project led to the highly acclaimed data.gov.uk site which now provides a portal to thousands of datasets.
In 2013, an international research team co-led by Dr Per Ola Kristensson, from the
University of St Andrews, created a new keyboard that enables faster thumb-typing on touchscreen devices.
The KALQ keyboard minimises thumb travel distance and maximises alternation between thumbs, enabling people to
EPSRC 1994-2014
In 2013, Dr Kristensson, who holds an
EPSRC Postdoctoral Research Fellowship, was recognised by the respected MIT
Technology Review as one of 35 top young innovators ‘most likely to change the world’. Previous winners include the founders and designers of Google,
Facebook, Apple and Tumblr.
In 2014, Dr Kristensson joined the
Department of Engineering at the
University of Cambridge.
In 2012, Nigel Shadbolt was awarded a
£6.2 million, five-year EPSRC Programme
Grant to lead the SOCIAM (Social Machines) project, which is researching pioneering methods of supporting purposeful human interaction on the World Wide Web.
The aim of the SOCIAM project is to enable us to build social machines that solve the routine tasks of daily life as well as its emergencies.
November 27: Frozen, the highest-grossing animated film of all time, starring Idina Menzel and Kristen Bell, is released
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2014
In 2014, Lizzy
Yarnold sped to gold medal success in the skeleton bobsleigh event at the Sochi Winter Olympics. But her achievement was not just a reward for her dedication and athleticism, it was also a triumph for UK engineering design.
Yarnold’s achievement at the Sanki Sliding
Centre came thanks, in part, to a sled designed by engineers Rachel Blackburn and James Roche (pictured) who work with
McLaren Applied Technologies, an offshoot of the Formula One company.
James and Rachel were EPSRCsponsored students studying for
Engineering Doctorates at the University of
Southampton when they designed ‘Arthur’, the sled that carried Amy Williams to gold medal victory in Vancouver in 2010. They were also key members of the British
Skeleton support team at Sochi 2014, and were there to witness Lizzy Yarnold’s triumphant gold medal-winning run.
Rachel Blackburn says: “The skills we learned from the Engineering Doctorate programme at Southampton, coupled with the ideas and knowledge of the British
Skeleton and UK Sport support staff, gave us a good grounding for implementing engineering solutions. Working with the athletes themselves helped us put our ideas into practice.
“The project also allowed us to develop new skills – from track testing, data analysis and prototyping through to full roll-out production of the sled.”
Since 2010, James and Rachel have been working with McLaren in Woking, Surrey to bring further improvements to the design of the sled, which they now call Mervyn
Blackroc – after an early sponsor and a fusion of their surnames.
James Roche says: “It was a fantastic honour to be able to work with British
Skeleton over the past eight years, supporting Amy, Lizzy and their fellow athletes in their respective successes.
“EPSRC funding was the catalyst that allowed Rachel and myself to pursue an academic and latterly engineering career in such a unique and challenging field.”
Picture courtesy UK Sport
EPSRC 1994-2014 June 12-July 13: The 2014 FIFA World Cup is held in Brazil, and is won by Germany
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EPSRC 1994-2014 September 27: The West African death toll from the Ebola virus reaches 3,000 lives
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2014
In 2014, researchers from the University of Sheffield, sponsored by EPSRC and Sellafield Ltd, developed a way to significantly reduce the volume of some higher activity nuclear wastes – reducing the cost of interim storage and final disposal.
The UK spends more than £80 million every year storing plutonium-contaminated nuclear waste safely. The current treatment method for non-compactable plutoniumcontaminated wastes involves cement encapsulation, a process which typically increases the overall volume.
The research project found that mixing plutonium-contaminated waste with blast furnace slag and turning it into glass reduces its volume by 85-95 per cent. It also effectively locks in the radioactive plutonium, creating a stable end product.
Lead researcher, Professor
Neil Hyatt, a co-investigator at the EPSRC Centre for Doctoral
Training in Nuclear Fission at the University of Sheffield, says:
“The overall volume of plutoniumcontaminated wastes from operations and decommissioning is enough to fill the clock tower of Big Ben seven times over. Our process would reduce this waste volume to fit neatly within just one tower.”
Also in 2014, EPSRC invested £4.9 million in a national research programme looking at ways of dealing with Britain’s nuclear waste.
The £8 million project, funded under the
RCUK Energy Programme, led by EPSRC, involves 10 UK universities, led by the
University of Leeds, and brings together the nuclear industry, the UK Government’s nuclear advisers and the country’s leading academic researchers.
More than 40 doctoral and postdoctoral researchers will work over the next four years on issues including how best to handle different types of spent fuel, packaging and storing waste, and dealing with nuclear sludges in ponds and silos at nuclear power stations.
Professor Simon Biggs, who leads the initiative, says: “The project is primarily focused on developing new technologies and providing confidence in the safe storage and disposal of legacy waste.
“The UK is a technology leader in this field and the core aim of this project is to maintain and further develop that skill base.
“This project will be a truly interdisciplinary effort. We have civil engineers, chemists, chemical engineers, robotics experts, radiochemists, mechanical engineers and material engineers all working together on
30 different projects.”
In addition to the £4.9 million invested by
EPSRC, funding and support for the project, which builds on an earlier EPSRC-funded
2007 research programme, will come from the universities and industry partners.
In 2014, an internet service which allows scientists to find antibodies for use in their research became the largest antibody search engine in a US$2 billion industry, and ranked number one by Google.
The CiteAb service was founded in 2013 by Dr Andrew Chalmers at the University of Bath following funding from an EPSRC
Knowledge Transfer Account.
Antibodies – proteins produced by the immune system in response to the introduction of a foreign body – have a variety of uses in basic research, diagnostic tests and therapeutics.
Dr Chalmers says: “One of the biggest problems for a researcher is being sure that the antibody they’re about to spend hundreds of pounds on is going to work.
They can waste time and money buying the wrong one, CiteAb solves this problem.
“We rank antibodies by academic citations as these are the best guide to whether an antibody is likely to work in the laboratory
– citations are independent and easily verifiable, and no one can pay to be the top hit.”
The CiteAb team work in collaboration with Bath-based Storm Consultancy and are currently exploring ways to use the data CiteAb generates to ensure the longterm success of this research as a commercial enterprise.
EPSRC 1994-2014 October 21: Olympic athlete Oscar Pistorius is sentenced to five years in prison for killing his girlfriend Reeva Steenkamp
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In 2014, EPSRC-funded researchers at the University of East Anglia (UEA) made an important step in the race to discover whether other planets could develop and sustain life.
Until now, computer simulations of habitable climates on Earth-like planets have focused on their atmospheres. But the presence of oceans is vital for optimal climate stability and habitability.
The research team, from the University of East Anglia’s schools of Mathematics and Environmental Sciences, created a computer simulated pattern of ocean circulation on a hypothetical ocean-covered
Earth-like planet.
Professor David Stevens, from UEA’s
School of Mathematics, says: “We found that heat transported by oceans would have a major impact on the temperature distribution across a planet, and would potentially allow a greater area of a planet to be habitable.
“Mars, for example, is in the sun’s habitable zone, but it has no oceans – causing air temperatures to swing over a range of
100 degrees Celsius.
“Oceans help to make a planet’s climate more stable so factoring them into climate models is vital for knowing whether the planet could develop and sustain life.
“This new model will help us to understand what the climates of other planets might be like with more accurate detail than ever before.”
In 2014, EPSRC-supported researchers at the University of Salford moved a step closer in developing technology to enhance the mobility of people with above-knee amputations.
Their solution lies in improving the energy efficiency of prosthetic legs.
EPSRC 1994-2014
When walking with a single prosthetic leg, above-knee amputees typically use up to
60 per cent more energy than people who are able-bodied, causing fatigue and a
40 per cent slower walking speed.
These difficulties can hinder an amputee’s mobility and thus affect their quality of life.
The energy storage and return capabilities of prosthetic legs are crucial to improving an amputee’s gait and mobility, but most prostheses only store and return significant energy below the knee and in an uncontrolled way.
To overcome these problems the team of engineers and prosthetists, working with leading prosthetics manufacturer Chas
A Blatchford, are exploring the potential for using hydraulic technology to harvest and store energy from the parts of the prosthesis that absorb power, and then return that energy to the parts that do useful propulsive work.
The results will be used to develop new prosthetic leg designs which have increased functionality and require less energy from the amputee.
Project leader, Professor David Howard, says: “This is an opportunity for truly transformative research, leading to more biomechanically-efficient prosthetic legs, enabling amputees to walk faster for longer and therefore lead more active lives.”
November 12: The Rosetta spacecraft’s Philae probe successfully lands on Comet 67P, the first time in history that a spacecraft has landed on such an object
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2014
In 2014, a consortium of UK scientists made an important step towards new malaria treatments by identifying a way to stop malaria parasites from multiplying.
The research team showed that the activity of an enzyme called NMT is essential for the survival and viability of the most common malaria parasite.
The study shows that NMT is involved in a wide range of essential processes in the parasite cell, including the production of proteins that enable malaria to be transmitted between humans and mosquitoes, and proteins that enable malaria to cause long-term infection.
The team are working to design molecules that inhibit NMT’s function, and hope to start clinical trials of potential treatments within four years.
The discovery is the culmination of a fiveyear project by a consortium of researchers from Imperial College London, the National
Institute for Medical Research, The
University of Nottingham, the University of York, and Pfizer. It is funded by EPSRC, the Medical Research Council and the
Biotechnology and Biological Sciences
Research Council.
In 2014, the EPSRC-supported
Optoelectronics Research Centre (ORC) at the University of Southampton celebrated its 25th anniversary.
In 2014, EPSRC-supported researchers at the University of Cambridge, led by EPSRC
Leadership Fellow Professor Julian Allwood, revealed that the construction industry is using almost double the amount of steel in buildings than is required by safety codes, which is having a dramatic impact on carbon emissions.
The team analysed 10,000 structural steel beams in 23 buildings across the UK and found that, on average, they were only carrying half the load they were originally designed for.
Buildings covered by the study were ‘typical’
UK steel-framed buildings constructed within the last five years, mainly schools, offices and residential buildings.
The study estimates that if the design of the 23 buildings were optimised to include only
EPSRC 1994-2014 the required amount of the material to meet safety standards it would save 1,027 tonnes of steel.
When scaled up to apply to the 290 million tonnes of steel used worldwide to construct buildings each year this would save
106 million tonnes of steel annually, averting
214 million tonnes of CO
2
emissions.
The research was conducted by the UK
INdemand Centre, led by Professor Allwood and funded under the RCUK Energy
Programme, led by EPSRC.
The centre, comprising the University of Cambridge, the University of Leeds,
Nottingham Trent University and the
University of Bath, focuses on ways to significantly reduce the use of both energy and energy-intensive materials in industry.
Professor Allwood is also a co-investigator at the EPSRC-funded Innovation and
Knowledge Centre for Smart Infrastructure and Construction, based at the University of
Cambridge, and is a senior staff member at the EPSRC Centre for Doctoral Training in
Future Infrastructure and Built Environment at Cambridge.
Since 1989, EPSRC has invested over
£20 million in the ORC, building on research led by its founding director, Professor
Sir David Payne. Blue-sky research by
Professor Payne’s team led to the invention of the world’s first telecommunications optical amplifier, a key device for internet expansion, and 15 years ahead of its time.
The ORC is now acknowledged as a world leader in photonics, optical telecommunication and high-power lasers, and has spawned a cluster of photonics companies to commercialise the research, generating revenues in excess of £100 million and creating more than 500 jobs. It has also produced over 700 doctoral-level alumni holding senior positions in industry and academia worldwide.
Ideas generated at the ORC help power the global internet, navigate airliners, cut steel, mark iPads, and manufacture life-saving medical devices.
Professor Sir David Payne, who in 2012 was knighted for his services to optoelectronics, says: “Thanks to long-term backing from
EPSRC, the University of Southampton has been a world leader in photonics research for 40 years, enabling the ORC to build
‘critical mass’ rare in academia.”
November 8: US President Obama authorises deployment of 1,500 additional troops to help train and advise Iraqi and Kurdish forces fighting IS militants
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In 2014, Professor Martin
Hairer, from the University of Warwick, became the first UK-based mathematician to win the prestigious Fields Medal since 1998.
Professor Hairer, who held an EPSRC
Advanced Research Fellowship from 2006-
2012, was recognised for his ‘outstanding contributions to the theory of stochastic partial differential equations, and in particular for the creation of a theory of regularity structures for such equations’.
The Fields Medal, internationally regarded as the world’s most prestigious award in mathematics, is awarded every four years and recognises the outstanding achievements of mathematicians aged under 40. Previous winners include Sir
Michael Atiyah (see page 59), in 1966.
In 2014, Chris Toumazou,
Regius Professor of
Engineering at Imperial
College London, was named Inventor of the Year in the Research category at the European Patent
Office’s awards for his work on a lowpower USB stick that decodes a patient’s
DNA within minutes.
Thanks to his work, DNA can be analysed outside a lab environment – helping medicine take a big step from healing illnesses to preventing them.
Invention for Professor Toumazou is in his blood. In the 1980s he developed the low-power processor vital to multi-channel cochlear implants invented by Erwin and
Ingeborg Hochmair.
These implants have restored hearing to more than 300,000 people since their introduction in 1986, the year Professor
Toumazou received his first EPSRC research grant – he has since been awarded over 20 more.
At the age of just 33, Chris Toumazou became the youngest professor ever to teach at Imperial College London – an achievement all the more remarkable for someone who left school at 16 with no qualifications.
At Imperial, he focused on ways of combining electrical engineering and microchip technology with biomedicine.
Today, Professor Toumazou, who has launched several highly successful companies to commercialise his work, co-leads the EPSRC Centre for Doctoral
Training in High Performance Embedded and Distributed Systems at Imperial.
In 2014, an
EPSRC-funded team from
Heriot-Watt
University and the
University of
Edinburgh came a step closer in developing a way to make low-fat cheeses and cakes as tempting as their full-fat equivalents.
The team, led by Dr Steve Euston of
Heriot-Watt University, produced modified proteins that easily break down into micro-particles and therefore closely mimic the behaviour of fats during food manufacture.
The proteins will enable manufacturers to remove much of the fat used in their products without compromising on product quality.
Protein-for-fat substitution is not a completely new idea, but to date it has been restricted to products such as yogurts.
The team has achieved particularly promising results in using proteins to replace eggs, an ingredient commonly used as a gelling agent in bakery items.
Substituting eggs for proteins not only cuts fat content, it could also reduce the cost of products and encourage consumers to eat more healthily.
The research is being taken forward by project partner Nandi Proteins, which is using the findings to extend its range of proteins with a view to food manufacturers incorporating them in new low-fat products that could start reaching the shops within two years.
Lydia Campbell, Chief Technology Officer for Nandi Proteins, says: “EPSRC funding allowed the scientific investigation of the underlying science of Nandi technology, and the outcomes will add significantly to the confidence with which the technology can be deployed across the
UK and internationally.
“They will also serve to broaden the innovation of our product range, and to compete with international companies.”
As part of an Innovate UK-supported
Knowledge Transfer Partnership, the research team is now also developing a computer model to help food manufacturers pinpoint the optimum level of protein-for-fat replacement for particular products.
EPSRC 1994-2014 November 15: World leaders gather in Brisbane for the G20 Summit, focusing on economic growth
In 2014, EPSRC invested in a new
£120 million national network of Quantum
Technology Hubs to explore the properties of quantum mechanics and how they can be harnessed for use in technology.
Quantum technologies offer potentially transformative impacts in key areas such as quantum metrology and sensors; quantum simulators; quantum computers and quantum secure communications.
The new network will involve 17 universities and 132 companies and will be funded by EPSRC from the £270 million investment in the UK National
Quantum Technologies Programme announced by the Chancellor in 2013.
The network will consist of four hubs, selected after a competitive peer- reviewed process, led by the universities of Birmingham, Glasgow, Oxford and York.
Sponsors of the new national network include Innovate UK, the Department for
Business, Innovation and Skills, National
Physical Laboratory, GCHQ, the Defence
Science and Technology Laboratory and the Knowledge Transfer Network.
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Picture courtesy Markus Unsold, Waldrappteam
In 2014, the mystery of why birds fly in
V-formations was finally solved with the help of lightweight sensors, fitted to the back of migrating birds.
The results from the project will prove useful in a variety of fields, for example aerodynamics and manufacturing.
A study of 14 Northern Bald Ibises showed that each bird synchronises its flapping to maximise the aerodynamic benefit of upwash from the wings of the bird in front.
The birds’ formation is so precise they are also able to avoid downwash from the birds ahead.
EPSRC 1994-2014
Dr Steve Portugal, lead researcher at the
Royal Veterinary College, University of
London, says: “The intricate mechanisms involved in V-formation flight indicate remarkable awareness and ability of birds to respond to the wingpath of nearby flock-mates.
“Birds in V-formation seem to have developed complex phasing strategies to cope with the dynamic wakes produced by flapping wings.”
These aerodynamic accomplishments were previously not thought possible for birds because of the complex flight dynamics and sensory feedback required.
The custom-built technology, developed with funding from EPSRC, captured the movements of every bird within the flock, recording its position, speed, and wing-flap during 43 minutes of migratory flight.
UK scientists worked together with conservation group Waldrappteam, which trained zoo-bred birds to follow a microlight to teach juvenile birds migration routes.
The research featured on the front cover of
Nature and appeared in the international print media. Dr Portugal was also interviewed for national and local radio including the Chris Evans Show on
BBC Radio 2.
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EPSRC 1994-2014
£4 billion
£1.74 billion
£800 million
2,800
45%
You can find out more about EPSRC and how you can work with us by visiting our website: www.epsrc.ac.uk as well as keeping up to date by following us on Twitter: www.twitter.com/
Design: Rachael Brown (rachael.brown@epsrc.ac.uk)
The Research Councils work collectively on issues of common concern via Research Councils UK.
Contributors: Phil Davies; Jack Snape; Grace Palmer;
Matt Shinn; John Yates
To provide feedback on this magazine, and to subscribe to print and/or electronic versions of
Pioneer, please e-mail pioneer@epsrc.ac.uk
Pioneer@epsrc.ac.uk
Contact: 01793 444305/442804
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