Loss of buoyancy control in the copepod Calanus finmarchicus

Jonathan H Cohen; Kim S Last; Jack Waldie; David W Pond

doi:10.1093/plankt/fbz036

Loss of buoyancy control in the copepod Calanus finmarchicus

Jonathan H Cohen
, Kim S Last
, Jack Waldie
, David W Pond

The Scottish Association for Marine Science, Scottish Marine Institute

Résultats de recherche › Revue par des pairs

3 Citations (Scopus)

52 Téléchargements (Pure)

Résumé

A mechanism is demonstrated that could explain large-scale aggregations of lipid-rich copepods in the surface waters of marine environments. Laboratory experiments establish that changes in salinity and temperature induce lipid-mediated buoyancy instability that entrains copepods in surface waters. Reduced hydrostatic pressure associated with forced ascent of copepods at fjordic sills, shelf breaks and seamounts would also reduce the density of the lipid reserves, forcing copepods and particularly those in diapause to the surface. We propose that salinity, temperature and hydrodynamics of the physical environment, in conjunction with the biophysical properties of lipids, explain periodic high abundances of lipid-rich copepods in surface waters.

langue originale	English
Pages (de - à)	787-790
Nombre de pages	4
journal	Journal of Plankton Research
Volume	41
Numéro de publication	5
Les DOIs	https://doi.org/10.1093/plankt/fbz036
état	Published - 14 oct. 2019

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title = "Loss of buoyancy control in the copepod Calanus finmarchicus",

abstract = "A mechanism is demonstrated that could explain large-scale aggregations of lipid-rich copepods in the surface waters of marine environments. Laboratory experiments establish that changes in salinity and temperature induce lipid-mediated buoyancy instability that entrains copepods in surface waters. Reduced hydrostatic pressure associated with forced ascent of copepods at fjordic sills, shelf breaks and seamounts would also reduce the density of the lipid reserves, forcing copepods and particularly those in diapause to the surface. We propose that salinity, temperature and hydrodynamics of the physical environment, in conjunction with the biophysical properties of lipids, explain periodic high abundances of lipid-rich copepods in surface waters.",

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AU - Cohen, Jonathan H

AU - Last, Kim S

AU - Waldie, Jack

AU - Pond, David W

N1 - © The Author(s) 2019

PY - 2019/10/14

Y1 - 2019/10/14

N2 - A mechanism is demonstrated that could explain large-scale aggregations of lipid-rich copepods in the surface waters of marine environments. Laboratory experiments establish that changes in salinity and temperature induce lipid-mediated buoyancy instability that entrains copepods in surface waters. Reduced hydrostatic pressure associated with forced ascent of copepods at fjordic sills, shelf breaks and seamounts would also reduce the density of the lipid reserves, forcing copepods and particularly those in diapause to the surface. We propose that salinity, temperature and hydrodynamics of the physical environment, in conjunction with the biophysical properties of lipids, explain periodic high abundances of lipid-rich copepods in surface waters.

AB - A mechanism is demonstrated that could explain large-scale aggregations of lipid-rich copepods in the surface waters of marine environments. Laboratory experiments establish that changes in salinity and temperature induce lipid-mediated buoyancy instability that entrains copepods in surface waters. Reduced hydrostatic pressure associated with forced ascent of copepods at fjordic sills, shelf breaks and seamounts would also reduce the density of the lipid reserves, forcing copepods and particularly those in diapause to the surface. We propose that salinity, temperature and hydrodynamics of the physical environment, in conjunction with the biophysical properties of lipids, explain periodic high abundances of lipid-rich copepods in surface waters.

KW - salinity

KW - temperature

KW - pressure

KW - lipid phase transition

KW - depth regulation

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DO - 10.1093/plankt/fbz036

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EP - 790

JO - Journal of Plankton Research

JF - Journal of Plankton Research

IS - 5

ER -

Loss of buoyancy control in the copepod Calanus finmarchicus

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