Abstract
There is a pressing need to quantify the risks of renewable energy developments such as offshore wind farms for protected populations. However, assessments are often based on incomplete data, or fail to consider variation in risk between sexes and at different times of year. We tracked northern gannets foraging from the world's largest colony (Bass Rock, Scotland) across five consecutive breeding seasons. We examine how seasonal and sex differences in behaviour affect the collision risk from planned and operational wind farms within their foraging range and assess the likely consequences for long-term population viability. Both sexes made shorter trips during chick-rearing than prior to chick-hatching, spent a greater proportion of time within wind farm sites and had an eight times greater potential collision risk during chick-rearing. Females made longer trips than males at both these times of year, flew higher and spent more time within wind farm sites, leading to three times greater collision risk for females. After accounting for the potential additional mortality from collisions, and assuming that the death of a parent also led to the loss of its offspring, the breeding population was projected to increase by 3.57% (95% CI: 2.16–5.15%) per year, compared with 6.56% (95% CI: 4.59–8.73%) in the absence of turbines, suggesting a negligible effect on population viability. However, additional mortality could result in greater immigration from neighbouring colonies, potentially affecting their viability and highlighting a need for research within a metapopulation framework to assess the impacts of offshore wind developments on vulnerable species across multiple connected sites.
Highlights
Marine environments are facing increasing pressure from human activities including fisheries, shipping and offshore developments such as oil and gas installations and wind farms (Halpern et al, 2019; O’Leary et al, 2020)
Gannets rearing chicks made much shorter trips than those recorded earlier in the breeding season in terms of both durations and distances travelled, with a smaller proportion of each trip spent resting on the sea surface during chick-rearing, presumably reflecting a benefit in return ing quickly to the colony at this stage of the season to feed dependent offspring (Hamer et al, 2007; Lane et al, 2019)
Trips recorded during the pre-hatching period probably included some that were from pre-laying or failed breeders in addition to birds whose partners were incubating, but they were consistently longer than trips by birds rearing chicks, with no overlap between these two stages of the season in interquartile ranges (IQRs) for trip durations by either sex and little overlap in IQRs for distances travelled (Table 2)
Summary
Marine environments are facing increasing pressure from human activities including fisheries, shipping and offshore developments such as oil and gas installations and wind farms (Halpern et al, 2019; O’Leary et al, 2020). Predicting the likely sizes of these effects on the populations of seabirds breeding at different colonies requires colony-specific information on the movements and behaviour of birds at sea, when there may be cumulative impacts on a breeding colony from several different wind farms (Green et al, 2016). Such data can be obtained using bird-borne data loggers (Wade et al, 2014; Thaxter et al, 2015) but the use of such technology is often restricted to periods when devices can be deployed and retrieved from birds, which may not be representative of the entire breeding season. Nesting birds may face greater constraints when they need to return frequently to the nest to feed dependent offspring than at earlier stages of the breeding season (Ito et al, 2010; Widmann et al, 2015)
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