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dc.contributor.authorMoyle, Alistair Ian
dc.date.accessioned2017-04-24T09:15:11Z
dc.date.issued2016-07-01
dc.description.abstractGlobal efforts to address climate change have recently introduced a new source of fatality risk to bats, from wind turbines. Bat fatalities have now been confirmed in varying magnitudes at wind energy facilities around the world. Research at large turbines and wind farms has started to produce a knowledge base regarding impacts upon bats, though many questions remain. Little, however, is known about risk levels at small and medium scale wind turbines. Equally, research regarding the impacts of turbines in the UK is limited. This thesis examines the impacts of small and medium scale wind turbines upon bats. Planning records of wind turbines in Wales and south west (SW) England were reviewed. Approved planning applications for single and double turbine sites were found to greatly outnumber those for larger scale wind farms. The large majority of single and double turbine approvals were also for small turbines. The potential impacts of turbine presence and density on current bat roost populations and population changes were analysed, finding no impact. An estimate of bat fatality rates at small and medium turbines was calculated, using a trained search dog to locate carcasses. An average fatality rate between 0.81 and 15.15 turbine-1 year-1 was estimated. The higher rate accounted for uncertainty in the monitoring protocol. Only 3 bat carcasses were however observed across all monitored turbines, suggesting more stringent monitoring would likely confirm a lower maximum annual fatality rate. Bat activity levels were also compared between the turbine location and differing habitat types. A disturbance effect was consequently identified in proximity to turbines during high wind speeds. Finally moderating influences of environmental weather and habitat conditions upon bat activity were confirmed. Social Network Analysis (SNA) methods were used to analyse bat movement networks within a small grid of bat detectors centred on each turbine. Associations were identified between bats’ movement routes and habitat structures present at sites, highlighting vulnerabilities to disruption. Furthermore bats actively used the turbine area, potentially for foraging purposes. Finally by assessing bats’ activity levels in response to a turbine noise playback experiment, small turbine noise was found to have no impact upon bat activity. Planning guidance regarding bats and small and medium turbines is highlighted as a priority for policy development.en_GB
dc.description.sponsorshipNatural Resources Walesen_GB
dc.description.sponsorshipNatural Environment Research Council (NERC)en_GB
dc.identifier.urihttp://hdl.handle.net/10871/27219
dc.language.isoenen_GB
dc.publisherUniversity of Exeteren_GB
dc.rightsLicensed for reuse under a Creative Commons licenceen_GB
dc.subjectbaten_GB
dc.subjectturbineen_GB
dc.subjectwinden_GB
dc.subjectrenewableen_GB
dc.subjectenergyen_GB
dc.subjectecologyen_GB
dc.titleThe Impacts of Small and Medium Wind Turbines on Batsen_GB
dc.typeThesis or dissertationen_GB
dc.date.available2017-04-24T09:15:11Z
dc.contributor.advisorMathews, Fiona
dc.descriptionThis thesis examines the impacts of small and medium scale wind turbines upon bats.en_GB
dc.publisher.departmentBiosciencesen_GB
dc.type.degreetitlePhD in Biological Sciencesen_GB
dc.type.qualificationlevelDoctoralen_GB
dc.type.qualificationnamePhDen_GB


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