Projected distributions of Southern Ocean albatrosses, petrels and fisheries as a consequence of climatic change

Krüger, Lucas; Ramos, Jaime A.; Xavier, José C.; Grémillet, David; González‐Solís, Jacob; Petry, Maria Virgı́nia; Phillips, Richard A.; Wanless, Ross M.; Paiva, Vítor H.

doi:10.1111/ecog.02590

Cited by 50 publications

(33 citation statements)

References 144 publications

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“…Another potential threat is the effect of climate change and how increasing temperatures might affect seabird species distributions. Krüger et al (2018) predicted that climate change will cause white-chinned petrels to shift their distributions by almost 10°to the south, although surprisingly Péron et al (2010b) predicted white-chinned petrels would shift their distributions northwards in response to climate change. White-chinned petrels are also impacted on their breeding islands by introduced predators, which occur on breeding islands supporting c. 42% of the worldwide population (see review of Southern Ocean islands with extant alien predators by Angel et al 2009).…”

Section: Conservation Implicationsmentioning

confidence: 99%

Year-round movements of white-chinned petrels from Marion Island, south-western Indian Ocean

et al. 2018

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White-chinned petrels Procellaria aequinoctialis L. are the most frequently recorded procellariiform species in the bycatch of Southern Hemisphere longline fisheries. Our study investigated the year-round movements of ten adult white-chinned petrels (seven breeders, three non-breeders/suspected pre-breeders) from Marion Island tracked with global location sensor (GLS) loggers for three years. Additionally, 20 global positioning system (GPS) tracks were obtained from breeding white-chinned petrels during incubation (n=9) and chick-rearing (n=11). All GLS-tagged birds remained, year-round, in the area between southern Africa and Antarctica, not making any major east/west movements. Three core areas (50% kernels) were utilized: around the Prince Edward Islands (PEI; incubation and early chick-rearing), c. 1000 km west of PEI (pre-breeding and early incubation) and around South Africa (non-breeding birds). The only area where 50% utilization kernels overlapped with intensive longline fishing effort was off the Agulhas Bank (non-breeding season). Our results confirm the lack of foraging overlap between the two subspecies; nominate birds (South Georgia/south-western Indian Ocean) utilize separate areas to P. a. steadi (New Zealand/sub-Antarctic islands), and thus should be treated as separate management units. Knowledge of the year-round movements of a vagile species, such as the white-chinned petrel, is important for its continued conservation.

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Section: Conservation Implicationsmentioning

confidence: 99%

Year-round movements of white-chinned petrels from Marion Island, south-western Indian Ocean

et al. 2018

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“…potential foraging habitat, although other factors such as changing wind regimes or changing conditions at breeding sites also need to be incorporated (Hazen et al 2013, Cimino et al 2016. The recent addition of future layers to the Bio-ORACLE data set (Jueterbock et al 2013) now makes data for the end of the 21st and the 22nd centuries more accessible to researchers (Krüger et al 2017). …”

Section: Sdms Of Seabird Distributions At Seamentioning

confidence: 99%

Avian SDMs: current state, challenges, and opportunities

Engler

Stiels

Schidelko

et al. 2017

Journal of Avian Biology

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Quantifying species distributions using species distribution models (SDMs) has emerged as a central method in modern biogeography. These empirical models link species occurrence data with spatial environmental information. Since their emergence in the 1990s, thousands of scientific papers have used SDMs to study organisms across the entire tree of life, with birds commanding considerable attention. Here, we review the current state of avian SDMs and point to challenges and future opportunities for specific applications, ranging from conservation biology, invasive species and predicting seabird distributions, to more general topics such as modeling avian diversity, niche evolution and seasonal distributions at a biogeographic scale. While SDMs have been criticized for being phenomenological in nature, and for their inability to explicitly account for a variety of processes affecting populations, we conclude that they remain a powerful tool to learn about past, current, and future species distributions -at least when their limitations and assumptions are recognized and addressed. We close our review by providing an outlook on prospects and synergies with other disciplines in which avian SDMs can play an important role.

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“…Researchers have used these methods to address specific aspects of seabird distributional ecology such as habitat suitability (Ceia et al 2012;Oppel et al 2012;Catry et al 2013;Louzao et al 2013;McGowan et al 2013;Scales et al 2016), identification of hotspots in the present and past (Louzao et al 2013), selection of potential conservation areas and potential climate change impacts (Krüger 2017). But, many of the more recent applications use ensemble modelling (Scales et al 2016;Krüger 2017) or incorporate seabird movement data (Clay 2016;Quillfeldt 2017) that, whilst increasing in quantity and availability, is nowhere near as prevalent or accessible as point observation data.…”

Section: Discussionmentioning

confidence: 99%

Biologically informed ecological niche models for an example pelagic, highly mobile species

Ingenloff¹

2017

European Journal of Ecology

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Background: Although pelagic seabirds are broadly recognised as indicators of the health of marine systems, numerous gaps exist in knowledge of their at-sea distributions at the species level. These gaps have profound negative impacts on the robustness of marine conservation policies. Correlative modelling techniques have provided some information, but few studies have explored model development for non-breeding pelagic seabirds.Here, I present a first phase in developing robust niche models for highly mobile species as a baseline for further development. Methodology: Using observational data from a 12-year time period, 217 unique model parameterisations across three correlative modelling algorithms (boosted regression trees, Maxent and minimum volume ellipsoids) were tested in a time-averaged approach for their ability to recreate the at-sea distribution of non-breeding Wandering Albatrosses (Diomedea exulans) to provide a baseline for further development. Principle Findings/Results: Overall, minimum volume ellipsoids outperformed both boosted regression trees and Maxent. However, whilst the latter two algorithms generally overfit the data, minimum volume ellipsoids tended to underfit the data. Conclusions: The results of this exercise suggest a necessary evolution in how correlative modelling for highly mobile species such as pelagic seabirds should be approached. These insights are crucial for understanding seabird-environment interactions at macroscales, which can facilitate the ability to address population declines and inform effective marine conservation policy in the wake of rapid global change. INTRODUCTION ABSTRACTBoosted regression trees; digital accessible knowledge; distribution modelling; Maxent; minimum volume ellipsoids; pelagic seabird distribution; Diomedea exulans KEYWORDS

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Projected distributions of Southern Ocean albatrosses, petrels and fisheries as a consequence of climatic change

Cited by 50 publications

References 144 publications

Year-round movements of white-chinned petrels from Marion Island, south-western Indian Ocean

Year-round movements of white-chinned petrels from Marion Island, south-western Indian Ocean

Avian SDMs: current state, challenges, and opportunities

Biologically informed ecological niche models for an example pelagic, highly mobile species

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