Breeding density, fine‐scale tracking, and large‐scale modeling reveal the regional distribution of four seabird species

Wakefield, Ewan D.; Owen, Ellie; Baer, Julia; Carroll, Matthew J.; Daunt, Francis; Dodd, Stephen; Green, Jonathan A.; Guilford, Tim; Mavor, Roddy; Miller, Peter I.; Newell, Mark A.; Newton, Stephen; Robertson, Gail; Shoji, Akiko; Soanes, Louise; Votier, Stephen C.; Wanless, Sarah; Bolton, Mark

doi:10.1002/eap.1591

Cited by 98 publications

(134 citation statements)

References 112 publications

(361 reference statements)

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“…These predators are constrained to a central location during the breeding season when they need to return to their nest to feed offspring, which results in strong intraspecific competition that can lead to individually varying foraging strategies (Ashmole 1963, Wakefield et al 2013, Wakefield et al 2017. In temperate species, intraspecific competition can be reduced by individuals specialising on a narrow foraging strategy, either in terms of behaviour or in repeatedly exploiting a specific area (Votier et al 2010.…”

Section: Introductionmentioning

confidence: 99%

Seasonal shifts in foraging distribution due to individual flexibility in a tropical pelagic forager, the Ascension frigatebird

Oppel¹,

Weber²,

Weber³

et al. 2017

Mar. Ecol. Prog. Ser.

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Predators exploiting tropical pelagic waters characterised by low fluctuations in seasonal temperature and salinity may require different foraging strategies than predators that can rely on persistently productive marine features. Consistent individual differences in foraging strategies have been found in temperate seabirds, but it is unclear whether such foraging specialisation would be beneficial in unpredictable tropical pelagic waters. We examined whether foraging trip characteristics of a tropical seabird were consistent between seasons and within individuals and explored whether seasonal changes could be explained by environmental variables. Ascension frigatebird Fregata aquila trips lasted up to 18 d and covered a total travel distance of up to 7047 km, but adult frigatebirds stayed within a radius of 1150 km of Ascension Island. We found that the 50% utilisation distribution of the population expanded southwestward in the cool season due to individuals performing more and longer trips in a southerly and westerly direction during the cool compared to the hot season. Individual repeatability was low (R < 0.25) for all trip characteristics, and we were unable to explain seasonal changes in time spent at sea using oceanographic or atmospheric variables. Instead, frigatebird usage per area was almost exclusively determined by distance from the colony, and although individuals spent more time in distant portions of their foraging trips, the amount of time spent per unit area decreased exponentially with increasing distance from the colony. This study indicates that, in a relatively featureless environment, high individual consistency may not be a beneficial trait for pelagic predators.

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Section: Introductionmentioning

confidence: 99%

Seasonal shifts in foraging distribution due to individual flexibility in a tropical pelagic forager, the Ascension frigatebird

Oppel¹,

Weber²,

Weber³

et al. 2017

Mar. Ecol. Prog. Ser.

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“…Previous studies provide strong evidence that habitat availability and competition are major drivers in the at-sea distribution of central place foragers (Ainley, Nur, & Eric, 1995;Raymond et al, 2015;Trathan et al, 2006;Wakefield et al, 2017). Optimal foraging theory suggests that animals will forage in areas abundant in resources, while minimizing the costs associated with travelling from the colony (MacArthur & Pianka, 1966).…”

Section: Habitat Preferences Of Chinstrap Penguinsmentioning

confidence: 99%

“…Additionally, the relative availability of habitats may vary between sites. This would result in variation in habitat selection between colonies and lead to models with poor predictive power (Matthiopoulos, 2003;Wakefield et al, 2017). Previous studies where habitat models for central place foragers maintained high predictive power when extrapolated into new locations frequently include availability (e.g., distance from the colony) and competition as important predictor variables (Raymond et al, 2015;Wakefield et al, 2011), and environmental variables were often less important.…”

Section: Ta B L Ementioning

confidence: 99%

Using habitat models for chinstrap penguins Pygoscelis antarctica to advise krill fisheries management during the penguin breeding season

Warwick-Evans

Ratcliffe

Lowther

et al. 2018

Diversity and Distributions

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Aim: To predict the at-sea distribution of chinstrap penguins across the South Orkney Islands and to quantify the overlap with the Southern Ocean krill fishery.Location: South Orkney Islands, Antarctica. Methods:Penguins from four colonies across the South Orkney Islands were tracked using global positioning systems (GPSs) and time depth recorders (TDRs). Relationships between a variety of environmental and geometric variables and the at-sea distribution of penguins were investigated using general additive models for the three main phases of the breeding season. Subsequently, the final models were extrapolated across the South Orkney archipelago to predict the at-sea distribution of penguins from colonies where no tracking data are available. Finally, the overlap between areas used by chinstrap penguins and the krill fishery was quantified. Results:The foraging distribution of chinstrap penguins can be predicted using two simple and static variables: the distance from the colony and the direction of travel towards the shelf-edge, while avoiding high densities of Pygoscelis penguins from other colonies. Additionally, we find that the chinstrap penguins breeding on the South Orkney Islands use areas which overlap with frequently used krill fishing areas and that this overlap is most prominent during the brood and crèche phases of the breeding season.Main conclusions: This is the first step in understanding the potential impacts of the krill fishery, for all colonies including those where no empirical tracking data are available. However, with the available data, it is not currently possible to infer an impact of the krill fisheries on penguins. With this in mind, we recommend the implementation of monitoring schemes to investigate the effects of prey depletion on predator populations and to ensure that management continues to follow a precautionary approach and is addressed at spatial and temporal scales relevant to ecosystem operation. K E Y W O R D SAntarctica, chinstrap penguin, fisheries overlap, habitat modelling, krill fishery, management, marine predator, Pygoscelis antarcticaThis is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…In the North Sea and Atlantic region long-term (up to 40 years) surveys for fish, fish larvae (Edwards et al, 2011;ICES, 2016), seabirds (Kober et al, 2010), and marine mammals (Hammond et al, 2013), as well as more recent use of tagged mammals and seabirds (Jones et al, 2013;Wakefield et al, 2017), have allowed the creation of seasonal and annual spatial distributions of either density or abundance depending on the data for the mobile species (see section on "Study Area and Species"). These outcomes can then be used in ecosystem models as predictors of the amount of future population change for a given stressor, that is, climate change or largescale renewable developments.…”

Section: Introductionmentioning

confidence: 99%

“…We use a selected group of important biological and physical variables (see section "Physical Environmental Variables" for more details) that will change with climate change and have been shown to be important to marine mammals and seabirds and their prey (Carroll et al 2015, Chavez-Rosales, Palka, Garrison, & Josephson, 2019, Sadykova et al, 2017, Wakefield et al 2017. The three aims of this study are first to compare joint model distributions of a range of contrasting seabird and mammal species from the present to future (2050) climate change projections.…”

Section: Introductionmentioning

confidence: 99%

Ecological costs of climate change on marine predator–prey population distributions by 2050

Sadykova

Scott

Dominicis

et al. 2020

Ecology and Evolution

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Identifying and quantifying the effects of climate change that alter the habitat overlap of marine predators and their prey population distributions is of great importance for the sustainable management of populations. This study uses Bayesian joint models with integrated nested Laplace approximation (INLA) to predict future spatial density distributions in the form of common spatial trends of predator-prey overlap in 2050 under the "business-as-usual, worst-case" climate change scenario. This was done for combinations of six mobile marine predator species (gray seal, harbor seal, harbor porpoise, common guillemot, black-legged kittiwake, and northern gannet) and two of their common prey species (herring and sandeels). A range of five explanatory variables that cover both physical and biological aspects of critical marine habitat were used as follows: bottom temperature, stratification, depth-averaged speed, net primary production, and maximum subsurface chlorophyll. Four different methods were explored to quantify relative ecological cost/benefits of climate change to the common spatial trends of predator-prey density distributions. All but one future joint model showed significant decreases in overall spatial percentage change. The most dramatic loss in predator-prey population overlap was shown by harbor seals with large declines in the common spatial trend for both prey species. On the positive side, both gannets and guillemots are projected to have localized regions with increased overlap with sandeels. Most joint predator-prey models showed large changes in centroid location, however the direction of change in centroids was not simply northwards, but mostly ranged from northwest to northeast. This approach can be very useful in informing the design of spatial management policies under climate change by using the potential differences in ecological costs to weigh up the trade-offs in decisions involving issues of large-scale spatial use of our oceans, such as marine protected areas, commercial fishing, and large-scale marine renewable developments.

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Breeding density, fine‐scale tracking, and large‐scale modeling reveal the regional distribution of four seabird species

Cited by 98 publications

References 112 publications

Seasonal shifts in foraging distribution due to individual flexibility in a tropical pelagic forager, the Ascension frigatebird

Seasonal shifts in foraging distribution due to individual flexibility in a tropical pelagic forager, the Ascension frigatebird

Using habitat models for chinstrap penguins Pygoscelis antarctica to advise krill fisheries management during the penguin breeding season

Ecological costs of climate change on marine predator–prey population distributions by 2050

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