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Spaceport is a Visitor Centre in an historic ferry terminal on the banks of the Mersey which showcases astronomy and space exploration. As a project it combines the research experience and knowledge of LJMU with the tourism credentials of Merseytravel. Merseytravel oversees the Merseyside public transport system, to promote and develop the transport network to meet the region's economic, social and environmental needs. As an attraction, Spaceport regularly exceeds visitor number predictions (currently at 70,000 per year) and brings in excess of £2M p.a. into a regeneration area. The continuing participation of LJMU has ensured that the centre remains up to date with new exhibits that link directly to LJMU's astronomical research and special events featuring LJMU astronomers and others, which are designed to extend its audience (e.g., for amateur astronomers or schools from inner-city areas).
To survive and grow in a shrinking UK market, the local engineering company SENAR set out to transform itself from a local company into one capable of winning international contracts. This required the company to make quality improvements, update skills and equipment, and develop relationships with international organizations. LJMU brought its programmes of astronomical research and instrumental development at national and international level into a symbiotic relationship with SENAR, collaborating on design and manufacture of advanced instrumentation and developing new capabilities within the company. It thereby:
Our high profile astronomy research discoveries in areas of public interest have allowed us to substantially increase the engagement of the public with science. Media appearances have led to a philanthropic donation of £200k to promote our science, the most successful public event series ever in Northern Ireland (engaging around 2000 people), a strategic partnership with Ireland's award winning science education centre W5 (reaching 26,000 people), and a 49% increase in applications to physics based degrees from NI students to UK HEIs. In 2008 we set three simple targets to substantially increase the public awareness of science and physics. The first was to increase our presence in the mass media (print, radio, TV, internet) to promote scientific research, and we have regularly reached audiences in excess of 295,000. The second was to increase the numbers of people attending science talks and events. The third was to substantially increase the application rate of school students to study physics and mathematics degrees. Through our outreach and engagement programme we have met, and surpassed, all of these targets. The impact of our research and our public outreach programme is a quantifiable societal change. Substantially more NI school students are now studying physics at third level UK HEIs.
Measurements made by unique radiosondes, conceived at and built by the university to count and size atmospheric aerosols, were used to validate UK Met Office models that forecast the amount and trajectory of the volcanic ash from the 2010 Eyjafjallajökull eruption. These first in situ measurements justified the authorities' cautious approach in grounding flights, thereby not jeopardising air passenger safety, despite huge pressure from commercial interests. The Met Office subsequently purchased further radiosondes for future deployment, and the underpinning particle detection technology is now licensed to a UK company for worldwide exploitation in areas of environmental monitoring, air quality and industrial safety.
Research on the anatomy, physiology and palaeoecology of pterosaurs by the Palaeobiology Group at Portsmouth University has had a wide and acknowledged impact, underpinning the creation and production of block-buster and pioneering television and film productions worldwide. The impact of this work is recognised by Sir David Attenborough, and by the producers of such TV successes as Walking With Dinosaurs and Flying Monsters 3D. These award-winning productions, highlighting our work, have reached a global audience and supported the generation of millions of pounds by the UK TV and film industry. Whilst the income generated is highly significant, perhaps their greatest impact lies in fostering a positive view of science, particularly in young audiences, by bringing cutting-edge evolutionary science direct to the World's film and TV screens.
Published and grant-awarded research in astrophysics and solar physics at UCLAN has underpinned a very large number of public lectures throughout the world (e.g. Edinburgh Science Festival, Harvard, NASA, IAC Tenerife, Perimeter Institute Canada, University of Cape Town, Astrofest London, etc.) during the impact reporting period 2008-2013, delivered by Professors Gibson, Kurtz, Ward-Thompson, Walsh and the rest of the staff in UoA9. The most prestigious of these have been delivered to large (typically several hundred to a few thousand people) sell-out audiences. Our staff have appeared on TV and radio to audiences of millions. In addition, public outreach events led by astrophysics and solar physics staff members at UCLAN have further increased the societal impact of our research.
University of Huddersfield research into knowledge engineering, domain modelling and machine learning has raised professional, industry and policymaker awareness of novel ways of designing more efficient, cost-effective and sustainable management networks. This is particularly the case in the field of transportation, where recognition of such techniques has significantly increased among stakeholders throughout the UK and across Europe. The research has been credited with informing a "step-change in thinking" and is now central to the £16m EPSRC Autonomous and Intelligent Systems Programme, which has attracted more than £4m in financial and in-kind support from hi-tech industries.
The university's Bayfordbury Observatory is a working observatory that engages with the public via six Open Evenings and approximately 50 group visits a year, offering access to a wide range of facilities. Many of the 4,000 visitors annually report that they develop a first or renewed `enthusiasm for astronomy', or become `inspired to learn more' about what they have seen or heard from our researchers; some young people enthuse about `now wanting to be a scientist'. Science teachers taking an RCUK `cutting-edge' CPD astrophysics course also say that they have gained an `increased understanding of the subject', and `increased confidence in its delivery to pupils'.
The international Square Kilometre Array (SKA) radio telescope, due for completion in the next decade, will be the world's largest astronomical instrument. It will be built by international industry at a cost of over €2B. The larger part will be sited in Africa (9 countries) with a complementary part in Australia. The impact to mid-2013 is on: i) international science policy and priorities (€26M); ii) multi-faceted human capacity building in Africa (401 bursaries); iii) business and employment involved in the construction of two large-scale SKA "precursor" instruments in South Africa and Australia (over €150M with 800 jobs in South Africa); iv) the local north-west economy (over €5M) where a new limited company to coordinate the SKA's design and construction has been established at Jodrell Bank.
The impact of this research has been of commercial benefit for TgK Scientific Ltd, a Wiltshire- based SME, who have successfully commercialised a FT-IR Stopped-Flow instrument. This has achieved market share as a result of incorporating an innovative cuvette designed and fabricated by the University of Birmingham's School of Biosciences. The company has sold nine of these instruments since they were first marketed in 2008, generating ~£200,000 in sales. This has made a substantial contribution to the company's total sales, most obviously in 2012 where sales of four instruments accounted for around 10% of their ~£800,000 turnover. The instrument allows the study of fast biological reactions by rapid scanning Fourier Transform Infrared Spectroscopy. The Birmingham contribution is a cuvette of a unique design that enables biological materials to be mixed and observed after 2-3 ms, allowing enzyme-catalysed reactions which have non- chromophoric substrates to be studied in physiological conditions. TgK have combined the cuvette with their stopped-flow drive system and a spectrometer produced by Bruker to make a complete apparatus; it is believed that this gives the instrument a unique functionality valued by a significant niche market.