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Research at Loughborough University during the REF period (and extending back at least three decades beyond that) has had a significant impact on national and international policy decisions governing the management of radioactive waste, one of the Grand Challenges facing society. The Unit's research ranges from deep geological disposal to abatement of marine discharges and remediation strategies for industrial radioactive waste, the latter safeguarding the competitiveness of the oil & gas and mineral processing sectors. This input has been crucial for revising the new Environmental Permitting Regulations and International Basic Safety Standards. Many of the Unit's doctoral graduates occupy important decision-making roles at key organisations such as the Nuclear Decommissioning Authority (NDA), Sellafield, Environment Agency, CEA (France) and the International Atomic Energy Agency (IAEA).
Research carried out by the University of Southampton has directly influenced the practice and behaviour of households, business, industry and government agencies. It has:
University of Huddersfield research in physical organic chemistry has delivered economic, industrial and societal benefits. It has led to process improvements in chemical manufacturing, most notably in the optimisation of the synthesis of antisense oligonucleotides and in the use of liquid ammonia as a solvent. It has also led to the development of new inhibitors of bacterial β-lactamases for use as antibacterials. The research team's expertise has been reflected in the success of IPOS (Innovative Physical Organic Solutions), a unit established in 2006 to carry out research in process and other areas of chemistry for the chemical industry. IPOS expanded significantly from 2009 to 2013 and has now collaborated with more than 150 companies, many of them based in Yorkshire/Humberside where regeneration is critically dependent on the success of new, non-traditional, high-technology firms and industries. Through these collaborative projects, IPOS has contributed to the growth and prosperity of both regional and national industry.
Accelerated Carbonation Technology (ACT) is an innovative solution to several key environmental issues - CO2 emissions to the atmosphere, sustainable use of resources and the reliance on use of virgin stone for construction. ACT rapidly stabilises industrial waste recycling it into valuable aggregate, thereby reducing the amount going to landfill. ACT simultaneously captures the greenhouse gas CO2, via the rapid production of carbonate, which solidifies the waste into a hardened product. ACT has been commercialised through two spin-out companies leading to the first commercial production of carbon negative concrete blocks, taking hazardous waste from the bottom to the top of the waste hierarchy.
The research of Prof Jim Frederickson and the Integrated Waste Systems Research group at The Open University (OU) has impacted industrial partners and government agencies in developing a sustainable approach to waste processes and treated products. In particular they have developed the biodegradability tests (DR4 and BM100/BMc) used extensively for the evaluation of Mechanical and Biological Treatment (MBT) waste plants, and also the Residual Biogas Potential (RBP) test for determining the stability of anaerobic digestates, which forms part of the BSI PAS110: 2010 specification. This work is a significant contribution to the development of sustainable waste management practices in the UK.
The research groups of Professor Laurence Harwood and Dr Michael Hudson (now retired) at the University of Reading have developed new and highly selective extractants for spent and reprocessed nuclear fuels. These novel extractants remove specifically the components in nuclear waste that have the highest levels of long-term radioactivity. The extracted components (minor actinides) may subsequently be converted — "transmuted" — into elements with greatly reduced radioactivity. Storage times for high-level nuclear waste can thus be reduced by a factor of a thousand, typically from 300,000 to 300 years. This significant advance in the management of nuclear waste means that next-generation nuclear power production will be safer, more economical and more sustainable, as well as increasing the wider acceptance of nuclear power as a viable alternative to fossil fuels. The newly-developed extractants are now available commercially through TechnoComm Ltd.
Cranfield University has been a key contributor to development of policy and regulatory guidance for industrial composting in collaboration with the UK environmental regulators, Government departments and with in-kind and financial support from the waste management industry. The growth of the industry in the UK has needed applied research to support the evolving policy.
Cranfield has characterised and quantified the nature and magnitude of airborne bioaerosol emissions and dispersion from composting for the first time. This research has fed into policy development on the regulation of facilities, and the practices of bioaerosol monitoring and site-specific bioaerosol risk assessment.
Carbon8 Systems (C8S) was founded on joint research between UCL and the University of Greenwich. The company has since developed a technology known as Accelerated Carbonation, which helps to reduce carbon dioxide (CO2) emissions by using carbon dioxide gas to treat waste materials and form artificial aggregate. In January 2013, C8S completed the first commercial plant for treating municipal solid waste incinerator (MSWI) fly ashes, designed to produce 1,000 tonnes per day of aggregate. Masonry products company Lignacite has also benefited commercially. It has used C8S's aggregate to develop an award-winning building block that captures more carbon dioxide than is emitted during its manufacture. Carbon8 Systems and its offshoot company Carbon8 Aggregates currently employ 11 people.
An innovative deep borehole disposal (DBD) concept for radioactive waste, pioneered at the University of Sheffield, resulted in significant impact on geological disposal strategy with an international reach. In the USA, our work contributed to a change in geological disposal strategy, with our concept described by the Director of Sandia National Laboratory as a "legitimate and a viable alternative [to the mined, engineered repository model] worthy of deeper consideration" [S1]. The Presidential Blue Ribbon Commission report on America's Nuclear Future recommended that DBD be taken forward to a practical pilot demonstration, now funded by the US Department of Energy (DOE) [S2]. Sheffield's work on DBD influenced Sweden's regulators and Environmental Court to reconsider approval of a mined repository by SKB. Our work has impacted on the UK approach to waste management, with DBD now included in the Nuclear Decommissioning Authority (NDA) [S3] bid to accelerate the Government's Managing Radioactive Waste Safely programme.
UK and international government departments, agencies and the nuclear industry have benefitted from improved understanding of environmental radioactivity and the development of novel, in situ gamma spectroscopy by researchers at the Scottish Universities Environmental Research Centre (SUERC, University of Glasgow). The provision of advice and novel data has helped to develop management, monitoring, regulation and human dose assessments for authorised and accidental releases of radionuclides, and to build plans for geological disposal facilities for high and intermediate level radioactive waste.