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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.
Palaeoenvironmental research in the Ica Valley of Peru's southern coast is revealing how agriculture acted with climate change to trigger major social upheaval in the past. This history is informing and educating people and policy-makers in the present, thereby sustaining sympathetic land use for the future. Specific impacts include a Defra-funded project on Peruvian biodiversity by the Royal Botanic Gardens at Kew (RBG), the implementation of Peruvian decrees regarding education and forest conservation, and the establishment of forest-management agreements with major landowners.
Angela Gurnell's research on the geomorphology, hydrology and plant ecology of urban water courses has led to the development of important new tools for the biophysical assessment and improved management of urban rivers. Known as the Urban River Survey (URS), these tools are accessed by the Environment Agency and River Trusts across London, and their application is supported with workshops and guidance provided by Gurnell and her team. The URS has been used to deliver morphological quality indicators for rivers across London; to appraise river restoration schemes; to develop catchment management plans; and to assess long-term changes in rivers. It is currently being developed to quantify and set targets for river improvement schemes in relation to their impact on river ecosystem services. Gurnell's work has made a distinct contribution to urban river improvements in Britain and Europe, particularly through her leadership in developing a European framework for assessing hydromorphology.
The zebra mussel is one of the world's most economically and ecologically important pests, but existing control approaches cause significant deleterious environmental effects. Researchers at the University of Cambridge have developed a `BioBullet' against zebra mussels, which encapsulates toxins in a harmless edible coat, enabling efficient, targeted product delivery and dramatically reducing environmental pollution. [text removed for publication] Further successful formulations are being developed by the researchers and the company for fouling in shrimp farms and enhancing shellfish aquaculture.
The way in which UK upland hay meadows are managed and restored to conserve botanical diversity has been largely determined by research carried out at Newcastle University. Increased post-war agricultural production has converted most species-rich upland hay meadows to species- poor rye-grass grassland so that today only 1070 ha (hectares) undisturbed hay meadow remains. The Newcastle research has been used by Natural England (an executive non-departmental public body responsible for England's natural environment) to produce targeted management prescriptions for 2500 ha of farmland in northern England and has informed National Park and AONB (Area of Outstanding Natural Beauty) management on best practice for successful restoration of hay meadows. The research has ensured the successful restoration of more than half of the remaining upland hay meadows in England.
Research by the University of Southampton into river processes and restoration has contributed significantly to the adoption of fluvial geomorphology as a tool for river management. The research quantified for the first time, the cost of sediment management in rivers to the UK economy and environment, arguing that improvements could be achieved by applying fluvial geomorphology. The research developed new evidence, tools and training that were adopted by river management agencies and consultants for the scoping, assessment and planning of projects. This has resulted in cost-savings through reduced river maintenance, improved river environments, and the creation of a new employment market for graduates with geomorphological training.
Carbon dioxide sequestration is the process by which pressured CO2 is injected into a storage space within the Earth rather than released into the atmosphere. It is one of the major ways that carbon dioxide emissions can be controlled.
Research since 2004 by applied mathematicians at the University of Cambridge into the many different effects that might be encountered during this process has had considerable impact on government and industry groups in determining how the field is viewed and how it should and might be industrially developed. The work played a major role in the CO2CRC conferences and was subsequently reported to the Australian Government by the CO2CRC chair and organisers.
Research led by the School of Geography at the University of Leeds has enabled, for the first time, the use of on-the-ground observations to evaluate directly the role of tropical forests in the global carbon cycle and to assess their sensitivity to change. Findings from the research have had a significant impact on international debates on the future trajectory of climate change and appropriate policy responses, and are influencing national-scale efforts across the tropics to manage forests in the face of climate change and to reduce carbon emissions resulting from deforestation [D, E, G, H, J]. The success of this Leeds-led initiative has been achieved through the extensive network of scientists involved in this global forest observatory: more than 250 scientists from over 50 institutions across more than 30 countries are now involved.
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.
Good quality water is essential for life on earth. The `Centre for Intelligent Environmental Systems' (CIES) has developed computer-based solutions for the assessment of river water quality by environmental agencies, working to improve the quality. CIES research has informed discussions and decisions of the UK Technical Advisory Group for the Water Framework Directive (UKTAG WFD). UKTAG WFD have selected the WHPT (Walley, Hawkes, Paisley & Trigg) method, for assessing river water quality throughout the UK, in the context of river management to meet the targets set in the Water Framework Directive (Directive 2000/60/EC from the European Union), which the UK government signed up to in 2000 (Beneficiaries: UKTAG WFD; Environment agencies; The public). Indirect impacts can also be attributed to CIES research, as it enables improvements of river quality, which triggers positive impacts on the natural environment, public health and quality of life (Beneficiaries: The public). CIES software has also been released to environment agency biologists as second opinion tools, thereby resulting in improved delivery of the public service provided by these biologists, when they use the software (Beneficiaries: Environment agencies; Environment agency biologists; The public).