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Inferring Cetacean Population Densities from the Absolute Dynamic Topography of the Ocean in a Hierarchical Bayesian Framework

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Title Inferring Cetacean Population Densities from the Absolute Dynamic Topography of the Ocean in a Hierarchical Bayesian Framework
Names Pardo, Mario A. (creator)
Gerrodette, Tim (creator)
Beier, Emilio (creator)
Gendron, Diane (creator)
Forney, Karin A. (creator)
Chivers, Susan J. (creator)
Barlow, Jay (creator)
Palacios, Daniel M. (creator)
Date Issued 2015-03-18 (iso8601)
Note To the best of our knowledge, one or more authors of this paper were federal employees when contributing to this work. This is the publisher’s final pdf. The article was published by the Public Library of Science and is in the public domain. The published article can be found at: http://www.plosone.org/.
Abstract We inferred the population densities of blue whales (Balaenoptera musculus) and short-beaked
common dolphins (Delphinus delphis) in the Northeast Pacific Ocean as functions
of the water-column’s physical structure by implementing hierarchical models in a Bayesian
framework. This approach allowed us to propagate the uncertainty of the field observations
into the inference of species-habitat relationships and to generate spatially explicit population
density predictions with reduced effects of sampling heterogeneity. Our hypothesis was
that the large-scale spatial distributions of these two cetacean species respond primarily to
ecological processes resulting from shoaling and outcropping of the pycnocline in regions
of wind-forced upwelling and eddy-like circulation. Physically, these processes affect the
thermodynamic balance of the water column, decreasing its volume and thus the height of
the absolute dynamic topography (ADT). Biologically, they lead to elevated primary productivity
and persistent aggregation of low-trophic-level prey. Unlike other remotely sensed variables,
ADT provides information about the structure of the entire water column and it is also
routinely measured at high spatial-temporal resolution by satellite altimeters with uniform
global coverage. Our models provide spatially explicit population density predictions for
both species, even in areas where the pycnocline shoals but does not outcrop (e.g. the
Costa Rica Dome and the North Equatorial Countercurrent thermocline ridge). Interannual
variations in distribution during El Niño anomalies suggest that the population density of
both species decreases dramatically in the Equatorial Cold Tongue and the Costa Rica
Dome, and that their distributions retract to particular areas that remain productive, such as
the more oceanic waters in the central California Current System, the northern Gulf of California,
the North Equatorial Countercurrent thermocline ridge, and the more southern portion
of the Humboldt Current System. We posit that such reductions in available foraging habitats during climatic disturbances could incur high energetic costs on these populations,
ultimately affecting individual fitness and survival.
Genre Article
Access Condition http://creativecommons.org/publicdomain/zero/1.0/
Identifier Pardo, M. A., Gerrodette, T., Beier, E., Gendron, D., Forney, K. A., Chivers, S. J., ... & Palacios, D. M. (2015). Inferring Cetacean Population Densities from the Absolute Dynamic Topography of the Ocean in a Hierarchical Bayesian Framework. PLoS ONE, 10(3), e0120727. doi:10.1371/journal.pone.0120727

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