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Research carried out by the University of Southampton has directly influenced the practice and behaviour of households, business, industry and government agencies. It has:
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.
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.
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.
Wastes management represents a major global environmental challenge. In the early 2000s Defra recognised that the UK's emphasis needed to change from managing waste to preventing it arising, and that Local Authorities must be equipped to produce cost-effective waste reduction plans. To this end, WRAP (Waste and Resources Action Programme) financed a major Local Authority training programme involving the Centre for Sustainable Wastes Management (CSWM) due to its track record of research expertise. Evaluation of this training demonstrated that over 90% of 204 delegates (from 33% of Local Authorities) developed a deeper understanding of waste prevention and 41% consequently upgraded their plans, embedding sustainable practice into their organisations and reducing arisings. The ultimate impact of this has been to save Local Authorities money and reduce the amount of waste going to landfill.
Research conducted at the University of Cambridge under an EPSRC grant between 1999 and 2002 established the viability of using microwave induced pyrolysis as a process for recovering clean, elemental aluminium and hydrocarbon liquids and gases from waste laminate packaging, thus preventing the need to send this material to landfill. The research has been commercialised by Enval Limited — a multi-award-winning University spin-off founded in 2006 that has attracted approximately £2M funding during the REF period and employs 7 people. A pilot scale unit has been operational since 2011, and the first commercial-scale unit has been constructed and has operated since April 2013.
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.
By identifying opportunities for waste reduction and recommending changes in forecasting, inventory management and packing, Cranfield research has shaped policy and practice in the reduction of food waste.
Working with the UK's major food retailers and UK government, Cranfield has investigated the causes of food waste to help organisations and influence the development of the Courtauld Commitment, a voluntary agreement to reduce product and packaging waste in the food supply chain. Reductions in product and packaging waste exceeded 8% between 2010 and 2012, building on earlier reductions, exceeding 500,000 tonnes in the period 2005-2009. Annual savings on product waste for UK food companies are estimated at £400 to 500 million for fresh fruit and vegetables and £110 million for fresh meat.
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).