Selection of diving strategy by Antarctic fur seals depends on where and when foraging takes place

We investigated the spatial and temporal distribution of foraging effort by lactating Antarctic fur seals Arctocephalus gazella at Heard Island using satellite telemetry and time-depth recorders. Two principal diving types were identified: ‘deep’ dives averaging 48.6 m, and ‘shallow’ dives averaging...

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Bibliographic Details
Published in:Marine Ecology Progress Series
Main Authors: Goldsworthy, S., Page, B., Welling, A., Chambellant, M., Bradshaw, C.
Format: Article in Journal/Newspaper
Language:English
Published: Inter-research 2010
Subjects:
Diving
Arctocephalus gazelle
Spatial foraging
Southern Ocean
Temporal variability
Antarctic
Kerguelen
Heard Island
Bradshaw
Corey
Antarc*
Antarctic Fur Seals
Arctocephalus gazella
Online Access:http://hdl.handle.net/2440/60665
https://doi.org/10.3354/meps08611
Description
Summary:We investigated the spatial and temporal distribution of foraging effort by lactating Antarctic fur seals Arctocephalus gazella at Heard Island using satellite telemetry and time-depth recorders. Two principal diving types were identified: ‘deep’ dives averaging 48.6 m, and ‘shallow’ dives averaging 8.6 m. Discriminant function analyses were used to assign dives based on their depth and duration. Generalised linear mixed-effects models of night dives (>80% of all dives) indicated both spatial and temporal effects on the distribution of deep and shallow dives. Deep dives were more common in the deeper shelf waters of the Kerguelen Plateau, and these dives predominantly occurred after sunset and before sunrise. In contrast, shallow dives were more common in slope waters on the southeastern margin of the Kerguelen Plateau in the hours either side of local midnight. We suggest that these 2 distinct diving types reflect the targeting of channichthyid (deep dives) and myctophid (shallow dives) fish, and are indicative of spatial and temporal differences in the availability of these 2 important prey groups. We also identified 3 distinct behavioural dive groups (based on multidimensional scaling of 19 diving and foraging trip parameters) that also differed in their spatial distribution and in their relative importance of deep and shallow dives. The present study provides some of the first evidence that diving strategies are not only influenced by where foraging takes pace, but also when. Simon D. Goldsworthy, Brad Page, Andrew Welling, Magaly Chambellant, Corey J. A. Bradshaw

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