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Low energy expenditure at the edge of a seabird's winter range suggests energy underpins the Abundant Centre Hypothesis
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  • Don-Jean Léandri-Breton,
  • Kyle Elliott,
  • Arnaud Tarroux,
  • Pierre Legagneux,
  • William Jouanneau,
  • Françoise Amélineau,
  • Frédéric Angelier,
  • Pierre Blévin,
  • Vegard Bråthen,
  • Per Fauchald,
  • Geir Gabrielsen,
  • Aurélie Goutte,
  • Sabrina Tartu,
  • B. Moe,
  • Olivier Chastel
Don-Jean Léandri-Breton
McGill University Department of Natural Resource Sciences

Corresponding Author:[email protected]

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Kyle Elliott
McGill University Department of Natural Resource Sciences
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Arnaud Tarroux
Norwegian Institute for Nature Research
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Pierre Legagneux
Laval University
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William Jouanneau
CEBC
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Françoise Amélineau
ECOBIO
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Frédéric Angelier
CEBC
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Pierre Blévin
Akvaplan-niva AS
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Vegard Bråthen
Norwegian Institute for Nature Research
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Per Fauchald
NINA Tromsø
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Geir Gabrielsen
Norsk Polarinstitutt
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Aurélie Goutte
Ecole Pratique des Hautes Etudes
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Sabrina Tartu
Centre National de la Recherche Scientifique
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B. Moe
Norwegian Institute for Nature Research
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Olivier Chastel
CEBC
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Abstract

Understanding how geographic range limits are shaped is a central and challenging question in ecology that has become particularly critical in the context of global environmental changes. While such limits are often studied for resident or breeding species, range limits are equally important for migratory species in winter when population regulation may occur due to limited resources in the non-breeding season. A central hypothesis in several theories for range limitations is that the density, fitness and performance of individuals decrease towards the edge of the range as organisms become maladapted when approaching the limit of their environmental tolerance (‘Abundant-centre Hypothesis’). Energy is a critical resource, especially in winter when environmental conditions deteriorate, and this hypothesis predicts that high energy expenditure (low performance) at the range limit would lead to rapidly dwindling body mass and reduced fitness. We investigated this hypothesis in an Arctic-breeding seabird wintering in the North-Atlantic, the black-legged kittiwake (Rissa tridactyla). From 2008 to 2019, we tracked 117 adult kittiwakes (n=176 tracks) with geolocation devices and saltwater immersion sensors to estimate the migratory strategies, time-activity budget and energy expenditure of individuals during winter, and estimated their reproductive success after their return to the colony during summer. Population density was indeed higher towards the center of the range. However, contrary to the predictions, the energy expenditure of individuals was higher at the centre of the range and decreased towards the edge. In contrast, there were no spatial differences in the reproductive success of individuals wintering at the centre versus at the edge of their range. We conclude that performance and fitness did not increase towards the centre of the wintering range, implying that although resource acquisition was likely higher at the abundant centre, energy expenditure was also higher, so that individual fitness was constant across the winter range.