North Atlantic winter cyclones starve seabirds

Each winter the North Atlantic Ocean is the stage for numerous cyclones, the most severe ones leading to seabird mass-mortality events called ‘winter wrecks’ (1–3). During those, thousands of emaciated seabird carcasses are washed ashore along European and North American coasts. Winter cyclones can...

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Bibliographic Details
Published in:Current Biology
Main Authors: Clairbaux, M, Mathewson, P, Porter, W, Fayet, A, Guilford, T
Format: Article in Journal/Newspaper
Language:English
Published: Cell Press 2021
Subjects:
Barents Sea
Alle alle
Davis Strait
fratercula
Fratercula arctica
Iceland
Labrador Sea
North Atlantic
rissa tridactyla
Uria aalge
Uria lomvia
uria
Online Access:https://doi.org/10.1016/j.cub.2021.06.059
https://ora.ox.ac.uk/objects/uuid:392e48f0-aeb7-4e21-9ea9-13cfc607386c
Description
Summary:Each winter the North Atlantic Ocean is the stage for numerous cyclones, the most severe ones leading to seabird mass-mortality events called ‘winter wrecks’ (1–3). During those, thousands of emaciated seabird carcasses are washed ashore along European and North American coasts. Winter cyclones can therefore shape seabird population dynamics (4,5) by affecting survival rates as well as the body condition of surviving individuals and thus their future reproduction. However, most often the geographic origins of impacted seabirds and the causes of their deaths remain unclear (6). We performed the first ocean-basin scale assessment of cyclone exposure in a seabird community, by coupling winter tracking data for ~1500 individuals of five key North Atlantic seabird species (Alle alle, Fratercula arctica, Uria aalge, Uria lomvia and Rissa tridactyla) and cyclone locations. We then explored the energetic consequences of different cyclonic conditions using a mechanistic bioenergetics model (7) and tested the hypothesis that cyclones dramatically increase seabird energy requirements. We demonstrated that cyclones of high-intensity impacted birds from all studied species and breeding colonies during winter, but especially those aggregating in the Labrador Sea, the Davis Strait, the surroundings of Iceland and the Barents Sea. Our broad scale analyses suggested that cyclonic conditions do not increase seabird energy requirements, implying that they die because of the unavailability of their prey and/or their inability to feed during cyclones. Our study provides essential information on seabird cyclone exposure in a context of marked cyclone regime changes due to global warming (8).

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