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This public outreach programme from Oxford links physics, particle accelerators and music through Einstein who was an enthusiastic violinist. The events have attracted a new audience to engage with science; have increased schoolchildren's interest in science and aspirations for science education; and have supported and inspired science teachers. More than 17,000 people have attended performances across seven countries, including over 8,000 at events for schools; audience satisfaction is very high. Extensive international media coverage has included BBC Radio and Radio New Zealand, television programmes in the US and New Zealand, and many newspaper and magazine articles. The programme has an average of 20 events per year and will continue.
Our development and demonstration of the world's first ns-FFAG accelerator (EMMA) and our expertise in exploiting and extending the capabilities of GEANT4 simulations have enabled us, in a relatively short time, to demonstrate societally significant applications of advanced particle accelerator technology. This research, which has garnered significant commercial and media attention, has demonstrated the feasibility of compact, reliable and affordable proton machines for cancer therapy [C], radioisotope production [A,B] and muon [F] and neutron [E] production, thereby offering UK industry a technological lead in a potentially enormous international market. Additionally, our research in accelerator driven technologies had played a significant role in establishing the scientific and political case for the construction of the 1.5b€ European Spallation Source in Lund, Sweden, and is influencing developments at Fermilab in the US [E,F].
The performance of absolute distance measuring systems has been improved in terms of accuracy, traceability, reliability and cost through the introduction of new methodology arising from research at the University of Oxford. This has brought commercial benefit to a German company making measurement systems, through the creation of a new product line. New capabilities for measurement have been delivered to a first customer in Germany. The research has also resulted in the establishment of new activity at the National Physical Laboratory, and influenced UK and European technology roadmaps for future manufacturing.
Since 1994, the university has pioneered the development of spatial light scattering for the rapid detection and classification of various types of airborne particle. This `particle thumbprint' technology, based on an analysis of the detailed 2-dimensional pattern of light scattered by each particle, has since found worldwide application.
Over the 2008-13 period, the technology was exploited by commercial companies and research organisations from the USA, mainland Europe, the UK and Japan in areas including military bioaerosol detection; atmospheric cloud microphysics and climate research; particle/powder process control; stack emissions monitoring; environmental pollution assessment; and, most recently, the real-time detection of hazardous airborne asbestos fibres.
Compressors developed at the Department of Engineering Science have formed a key component of the cryocoolers used to cool the infra-red sensors on satellites. Their low mass has trimmed almost $250k from the cost of individual satellite missions. Sixty seven have been sold to date, with sales totalling £2.8M between January 2008 and July 2013; three units are currently in Earth orbit with another nine planned to follow in 2014. A specialised version has been developed to achieve extremely low temperatures, with prototypes already built for the Mid Infra-Red Instrument (MIRI) that will form part of the James Webb Space Telescope.
Research conducted since July 2008 by the University of East London in collaboration with Control Techniques Dynamics (CTD), a leading manufacturer of Permanent Magnet Synchronous Motors (PMSMs), has led to the development of a software tool called the PMSM analyser. This tool has helped CTD to improve its motor design methodology by incorporating electromagnetic, thermal and cost models, together with genetic algorithms. In turn, the design optimisation allowed CTD to enhance motor performance and reduce manufacturing time by 30-40%, leading to an increase of 20% in company sales between 2008 and 2013. During the same period the company was able to cut materials usage by 15%.
A smartphone application, LHSee, has enabled members of the public to understand better one of the experiments at the Large Hadron Collider, by presenting interactive displays of real collision events from the ATLAS experiment including those contributing to the Higgs boson discovery. The software has enabled users to understand and be engaged with the process of discovery at the LHC and has raised aspirations for further engagement with science and the study of physics. It has been downloaded over 60,000 times and has achieved excellent user reviews and awards.
The discovery of the Higgs boson at the Large Hadron Collider (LHC) has been one of the biggest science stories in recent years. John Ellis of the KCL Physics Department has significantly enhanced the impact of this scientific breakthrough by engaging the general public around the world with the landmark scientific developments. Based on his original research on the Higgs boson and other aspects of LHC physics, and drawing on work of his colleagues, Ellis has given 76 outreach talks since April 2011 in the UK and in 24 other countries. He has participated in five cultural festivals, given a Youtube presentation with over 500,000 views, made many BBC appearances and given expert analysis and interviews to UK and international print and broadcast media. The reach of the impact is truly global with an audience estimated in the millions.
Between January 2008 and July 2013, over 10,000 key stage 4 school students and their teachers directly engaged with active research of the Cavendish Laboratory, Department of Physics, University of Cambridge through an annual interactive 3 day exhibition, titled "Physics at Work". In 2012 the event attracted 31 non-selective state schools and 17 selective/independent schools, 23 of which had visited the exhibition 3 or more times previously- a testament to its success. Building on the enthusiasm that the students showed during their participation in the event, teachers noted an increase in the number opting to study A-level physics and stated that those previously with no interest left with a very positive image of the subject.
Impact: Economic gains PHYESTA designed 8% of the area of the computer chip for IBM's most recent BlueGene/Q supercomputer product. Global install base of design exceeds $500M.
Significance: Unique experiment in co-design at the cutting edge of technology. Adopted by both IBM and Fujitsu, who have led in Green500 energy efficiency and top500 supercomputer rankings.
Reach: This supercomputer architecture has been installed in labs in the UK, the US, the EU, and Japan and is accelerating computational science and advanced manufacturing around the globe. In the UK the BlueJoule system installed in the Hartree center at Daresbury is driving HPC uptake in the advanced manufacturing sector.
Beneficiaries: IBM, Fujitsu, computational science and the HPC community worldwide.
Attribution: This work was led by Dr Peter Boyle (School of Physics & Astronomy, University of Edinburgh) in collaboration with Columbia University and IBM.