Three-dimensional space use during the bottom phase of southern elephant seal dives

Abstract Background In marine pelagic ecosystems, the spatial distribution of biomass is heterogeneous and dynamic. At large scales, physical processes are the main driving forces of biomass distribution. At fine scales, both biotic and abiotic parameters are likely to be key determinants in the hor...

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Bibliographic Details
Published in:Movement Ecology
Main Authors: Yves Le Bras, Joffrey Jouma’a, Christophe Guinet
Format: Article in Journal/Newspaper
Language:English
Published: BMC 2017
Subjects:
Diving behaviour
Three-dimensional path reconstruction
Prey density
Prey distribution
Prey patch
Biology (General)
QH301-705.5
Elephant Seal
Elephant Seals
Southern Elephant Seal
Southern Elephant Seals
Online Access:https://doi.org/10.1186/s40462-017-0108-y
https://doaj.org/article/6c08792ca7824b029cc8d82f669a1ef7
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Summary:Abstract Background In marine pelagic ecosystems, the spatial distribution of biomass is heterogeneous and dynamic. At large scales, physical processes are the main driving forces of biomass distribution. At fine scales, both biotic and abiotic parameters are likely to be key determinants in the horizontal and vertical distribution of biomass, with direct consequences on the foraging behaviour of diving predators. However, fine scale three-dimensional (3D) spatial interactions between diving predators and their prey are still poorly known. Results We reconstructed and examined the patterns of southern elephant seals 3D path during the bottom phase of their dives, and related them to estimated prey encounter density. We found that southern elephant seal tracks at bottom are strongly dominated by a single horizontal direction. In high prey density areas, seals travelled shorter distances but their track remained strongly orientated according to a main linear direction. Horizontal, and more importantly, vertical deviations from this main direction, were related negatively to the estimated prey density. We found that prey encounter density decreased with diving depth but tended to be more predictable. Conclusion Southern elephant seal behaviour during the bottom phase of their dives suggest that the prey are dispersed and distributed into layers in which their density relates to the vertical spread of the layer. The linear trajectories performed by the elephant seals would allow to explore the largest volume of water, maximizing the opportunities of prey encounter, while travelling great horizontal distances.

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