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Professor Gowing and his associates' research demonstrated the sensitivity of grassland species to soil moisture regime. They developed a method for quantifying the relationship between plant community composition and soil moisture regime which showed that controlling water levels in traditional ways led to conservation of important plant species and/or enhanced diversity. This research led to the Environment Agency issuing practical guidelines to site managers for these internationally important sites, with a lead section written by Gowing. Advice has been given directly to owners and managers via the Floodplain Meadows Partnership led by the OU, engendering parallel studies abroad.
Scientists at the Institute of Zoology (IOZ) led the development of the IUCN Red List, the foremost tool for assessing species extinction risk. We further developed systems to evaluate the status of biodiversity at the national level (National Red Lists), quantify population changes (Living Planet Index) and robustly measure changing biodiversity (Sampled Red List Index), and global indicators of the status of biodiversity for the Convention on Biological Diversity (CBD). These are used to drive conservation policy and public engagement by Inter-Governmental and Non-Governmental Organisations, and national governments, and underpin measurement of adherence to CBD Targets for 2010 and 2020.
The application of legislation and policy protecting European maerl habitats under the EC Habitats Directive has been strengthened by research at QUB showing that maerl, coral-like seaweed, is slow-growing, intolerant of disturbance and burial, and supports high biodiversity. A new marine Natura 2000 Special Area of Conservation (SAC) in Northern Ireland was designated for maerl in 2010. Maerl beds in the Fal and Helford SAC, the largest in England, were protected in 2009 from channel dredging until a Scientific Panel including a QUB academic has considered the results of a maerl-relocation trial in 2013.
The eradication of alien invasive species is a conservation priority, but is rarely attempted in mainland areas given the logistical and economic challenges of species control over large areas. Any effective control programme must be underpinned by robust scientific understanding of the population ecology of the target species to ensure control is appropriately focussed and directed, and that efforts are not swamped by compensatory dispersal from neighbouring regions.
A University of Aberdeen study of water vole population ecology recognised sharp declines in numbers and identified the invasive, predatory American mink as a primary driver of population extinction. The world's largest mainland species eradication programme was then put in place by Aberdeen, involving many hundreds of volunteers. It has successfully removed breeding mink from over 10,000 km2 of Scotland and secured the future of an iconic symbol of natural heritage. This conservation success story is now used as a template for the management of invasive mink in other eradication initiatives in Scotland and internationally.
The research thereby impacted the conservation of natural resources and policy and planning of management.
York research developed the essential common ground of our understanding of invasive alien species, highlighting their effects on biodiversity and their economic costs. The conceptual frameworks developed at York underpin all subsequent policies and practical strategies in 2008-2013, including the Convention on Biological Diversity (CBD), whose 193 signatory countries are legally bound to "prevent the introduction of, control or eradicate those alien species which threaten ecosystems, habitats or species". UK and international policies and strategies to prevent new introductions and control established aliens stem directly from York research.
Identification of rare plant species on nature reserves at Malham (Yorks.) and Morvich (W. Scotland) led to site managers developing sympathetic management approaches to ensure the species' conservation. These are detailed in management plans and include reduction in grazing and introduction of population census to assess management success. In addition, incorporation of the discoveries into plant guides has led to increased awareness of the two species which in turn has drawn naturalists to view and photograph them. Thus the research at Edge Hill has led to the conservation of and increased awareness of a rare component of the UK flora.
Preziosi and his research group have taken a leading role in conducting biodiversity research in the Ecuadorian Amazon, working in collaboration with national and local governments and indigenous communities. It is critical to monitor and conserve biodiversity in the Ecuadorian Amazon and preserve this unique habitat for local, national and international benefit. Preziosi's research group have demonstrated that indigenous people can be trained to monitor biodiversity accurately. The impact of introducing these new skills to local people in the Payamino community is that they have been empowered to locally monitor and adaptively manage their own resources. By educating local people about the importance of biodiversity, Preziosi's research group have changed the behaviours and attitudes of the community, leading to reduced participation in environmentally harmful practices.
Research on the population biology of the stag beetle at Royal Holloway has created impact on the environment (species conservation through an increase in available habitat and in known breeding sites), impact on public policy (production of a species action plan and an EU Directive and the management of woodland habitats), and impact on society (change in public understanding). Using a `Citizen Science' approach, over 250 volunteers have engaged with this research in population surveys and over 1,000 have helped to create breeding sites. The research has helped to implement conservation policy decisions in the UK and EU and has produced many public information guides. It also has resulted in a radically revised Joint Nature Conservation Committee (JNCC) national Biodiversity Action Plan (BAP) for the species. Furthermore, the research has created impact on practitioners (through enhancement of teaching practices) and brought practical conservation biology into schools, improving the teaching of the National Curriculum at KS2 and 3.
The impacts in this case study arise from research into the pathways, and processes by which novel vectors and vector borne diseases may be introduced into the Galapagos islands. On the basis of the research, the Ecuadorian government changed national legislation on biosecurity, and implemented a suite of new mitigation measures including requiring all aircraft flying to Galapagos to have disinsection treatments, and banned direct international flights to the archipelago. The work increased general awareness of potential impacts from introduced diseases on Galapagos biodiversity, and the need to improve the biosecurity of the islands, influencing policy decisions in a range of other international organisations including UNESCO. The globally important biodiversity of Galapagos is the basis of a significant fraction of the tourist and national economy of Ecuador.
The Lake Naivasha region is a globally-important wildlife sanctuary, international tourism destination and the world's centre for cut flower export. Professor David Harper has led sustained ecological research over a number of years, and this has led to significant impact in terms of helping to resolve massive ecological degradation at Kenya's Lake Naivasha. The research has inspired the creation of a Lake management agency through involvement of HRH Prince of Wales — `Imarisha' — and which incorporated Leicester's recommendations into its Sustainable Development Action Plan (2012-17), in turn underpinning increasing sales of Fair Trade products and ensuring the sustainability of Naivasha's ecosystem services for future generations.