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Research at the University of Exeter on the links between the Amazon rainforest and climate change has influenced international climate policy, has directly assisted Brazilian environmental policymakers, and has received international media coverage. The underpinning research spans the vulnerability of the rainforest to anthropogenic climate change and the mechanisms behind the Amazonian droughts of 2005 and 2010. Impact has been achieved by stimulating public debate through the media, by contribution to science-into-policy documents produced by the World Bank and for the United Nations Framework Convention on Climate Change (UNFCCC), and by direct face-to-face interaction with UK and Brazilian policymakers.
Innovative geochemical research led by Selby at Durham has permitted savings of up to $70M in global mineral and petroleum exploration programmes (e.g., Andes of S. America; West of Shetlands oilfields). Selby's research has developed a unique geochemical toolbox using rhenium, osmium, platinum and palladium that constrain more accurate geological models leading to better reserve predictions. The toolbox provides previously unavailable geological time constraints and source identification of resources (e.g., copper, gold, crude oil) that gives mineral and/or petroleum companies an enhanced economic advantage by improving reserve estimates and/or reducing exploration budgets and/or minimising the environmental impacts of exploration.
The Arctic is undergoing faster rates of climate change than most other regions of the world, with major global consequences. Since the 1990s, Professor Callaghan and co-workers at Sheffield have been at the forefront of determining climate change impacts on Arctic ecosystems. This research has directly led to, and fed into, invited authorship and major co-ordination roles in the authoritative international synthesis reports on climate change impacts commissioned by the Arctic Council and the Intergovernmental Panel on Climate Change (IPCC). Through these reports our findings have been widely communicated to international policymakers, the media and society. Callaghan and colleagues have provided policy advice directly to ministers, ambassadors, climate negotiators, and other leaders through face-to-face meetings and presentations, and influenced policy debates at regional to international levels. They have actively engaged in knowledge- exchange activities with Arctic indigenous societies, which are improving those societies' strategies for adaptation to climate change. Through public lectures, the media and authorship of a commissioned textbook, the Sheffield research findings have increased public understanding and influenced the A-level Geography curriculum.
Protecting London from the threat of flooding is of prime importance to the nation. Work in the Unit on regional sea-level rise and on the effect of storm surges was used in the Environment Agency's Thames Estuary 2100 (TE2100) plan to assess potential change in risk. The Unit's work estimated a very unlikely maximum rise in sea level of 2.7m by 2100, considerably lower than the previous worst-case scenario of 4.2m. It confirmed that 90 centimetres was the figure that should be used for developing the plan. TE2100 concluded that a second Thames Barrier (estimated cost £10-20 billion at today's prices) would not be needed not by 2030, but may be needed by 2070. Our results have been used to define procedures for the monitoring of regional sea and Thames water levels over the next few decades, and to review decision-making procedures to ensure that the risk of flooding in London is kept within acceptable levels, while avoiding unnecessary costs
The BUGS research project (1999-2007) at Sheffield was the first large-scale study to reveal the importance of domestic gardens for urban biodiversity. The evidence gathered showed, for the first time, that the extent of gardens, their unique features, and the biodiversity they support makes them a nationally important ecological resource, contributing enormously to conservation and human-nature interactions in urban environments. The results were reported in a series of 13 ISI-listed papers, a popular book and two articles in British Wildlife. The research has had impacts across many audiences and applications ranging from evidence for planning policy changes, through the science to support advisory and campaign groups, to informing public awareness of the merits of individual garden management practices. BUGS research has been a key catalyst in the increased recognition of the importance of gardens in supporting urban biodiversity.
Research by Professors Tamara Galloway, David Melzer, and Michael Depledge at Exeter identified, for the first time, associations between exposure to the widespread environmental contaminant bisphenol A (BPA) and changing incidences of disease. The research showed that higher exposures to BPA are associated with an increased risk of cardiovascular disease and hormonal changes. The research has influenced policy development worldwide, raised public awareness of environmental chemical health risks, stimulated public debate and critical media analysis, and is stimulating enhanced public, policy-maker and business interest in anthropogenic chemicals in the environment and their implications for human health.
Vincent Gauci and The Open University (OU) Ecosystems Research Group have demonstrated human influences over exchanges of carbon within vulnerable, temperate and tropical wetland ecosystems, which are the largest source of the powerful greenhouse gas methane to the atmosphere. The group's work showing that acid rain pollution suppresses methane emissions from wetlands has influenced policy in the UK, particularly peatland restoration, where the group has had direct interaction with users. The group's work on carbon balance resulting from deforestation, drainage and fires in the carbon-rich Bornean peat swamp has also informed IPCC methodologies for carbon balance calculations in its 2013 Wetlands Supplement.
Research performed at the University of Leeds allows the petroleum industry to reduce radically the amount of time that taken to estimate the key properties of tight sandstones containing natural gas. These properties largely determine whether gas fields are economically viable. Tests used in the past have taken between six months and two years to complete; with the Leeds research, results can now be obtained in less than one day — a radical improvement. Industry has used the results to justify drilling new prospects and to improve understanding of the controls on gas and water production in existing fields, which has shaped appraisal and production strategies.
We conducted research on the impact of land-use change that has resulted in international action to improve forest management. Our research demonstrated that clearing forests to grow crops for biofuels leads to large carbon emissions. In light of these findings, the UK Government amended its biofuel policy to include mandatory sustainability criteria. Leeds researchers co-established with a number of businesses the charity United Bank of Carbon, resulting in the investment of £1.5 million and the protection of 200,000 hectares of forest. Our research underpinned a forest-based climate mitigation scheme resulting in the investment of an additional £440k in forest protection.
Research carried out at the University of Leeds has been used to develop data sets that are now routinely used in offshore oil exploration to identify prospective areas faster, and with reduced cost. New techniques applied to satellite altimeter data have been used to compute gravity anomalies in marine areas with increased accuracy and reliability relative to earlier products. These anomalies have been developed during the REF period in association with a University of Leeds spin-out company (Getech) into a global data set, which has been sold and licensed extensively within the hydrocarbon exploration industry. The global data set has delivered economic and reputational benefits to Getech, and has been employed by oil companies in more than 50 exploration projects per year. Shell values the improved gravity data at $2.5M per project.