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• W2801542783 abstract "MEPS Marine Ecology Progress Series Contact the journal Facebook Twitter RSS Mailing List Subscribe to our mailing list via Mailchimp HomeLatest VolumeAbout the JournalEditorsTheme Sections MEPS 599:239-251 (2018) - DOI: https://doi.org/10.3354/meps12624 Moult location and diet of auks in the North Sea inferred from coupled light-based and isotope-based geolocation Katie St. John Glew1,*, Sarah Wanless2, Michael P. Harris2, Francis Daunt2, Kjell Einar Erikstad3,4, Hallvard Strøm5, Clive N. Trueman1 1Ocean and Earth Science, University of Southampton, Waterfront Campus, Southampton SO143ZH, UK 2Centre for Ecology & Hydrology, Bush Estate, Penicuik EH26 0QB, UK 3Norwegian Institute for Nature Research, Fram Centre, 9296 Tromsø, Norway 4Centre for Biodiversity Dynamics, Department of Biology, Norwegian University of Science and Technology, 7491 Trondheim, Norway 5Norwegian Polar Institute, Fram Centre, Postbox 6606 Langnes, 9296 Tromsø, Norway *Corresponding author: katie.stjohnglew@soton.ac.uk ABSTRACT: Many pelagic seabirds moult their feathers while at sea, which is an energetically costly behaviour. Mortality rates during moult can be high, so spatial and trophic ecology during this critical period is important for understanding demographic patterns. Unfortunately, individual foraging behaviours specifically linked to at-sea moulting are commonly unclear. This paper combines 2 different approaches to geolocation: data from bird-borne geolocation loggers and stable-isotope assignment using carbon and nitrogen isotope maps (isoscapes). Coupling 2 geolocation processes allows some uncertainties associated with isotope-based assignment to be constrained. We applied this approach to quantify species-specific foraging locations and individual trophic variability during feather regrowth in 3 sympatric auk populations breeding on the Isle of May, Scotland (common guillemot Uria aalge, razorbill Alca torda and Atlantic puffin Fratercula arctica). Inferred foraging areas during moult differed between species and feather types. Guillemots likely underwent moult within the southern North Sea, razorbills along the east coast of England and into the southern North Sea and puffins off the east coast of Scotland. Estimates of individual trophic position varied considerably within feather types (up to 1 trophic level difference between individuals), among feather types grown during different time periods and across the 3 species, with guillemots consistently foraging at higher trophic positions than razorbills and puffins. Used in combination, these methods better constrain foraging areas during moulting, and provide a technique to explore individual differences and flexibility in foraging strategy, which is valuable information for both seabird conservation and marine spatial planning. KEY WORDS: Isoscape · Trophic ecology · Foraging · Moult · Atlantic puffin · Common guillemot · Razorbill Full text in pdf format PreviousNextCite this article as: St John Glew K, Wanless S, Harris MP, Daunt F, Erikstad KE, Strøm H, Trueman CN (2018) Moult location and diet of auks in the North Sea inferred from coupled light-based and isotope-based geolocation. Mar Ecol Prog Ser 599:239-251. https://doi.org/10.3354/meps12624 Export citation RSS - Facebook - Tweet - linkedIn Cited by Published in MEPS Vol. 599. Online publication date: July 12, 2018 Print ISSN: 0171-8630; Online ISSN: 1616-1599 Copyright © 2018 Inter-Research." @default.
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• W2801542783 date "2018-07-12" @default.
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• W2801542783 title "Moult location and diet of auks in the North Sea inferred from coupled light-based and isotopebased geolocation" @default.
• W2801542783 cites W1495817180 @default.
• W2801542783 cites W1691734291 @default.
• W2801542783 cites W1965619678 @default.
• W2801542783 cites W1969139211 @default.
• W2801542783 cites W1978680801 @default.
• W2801542783 cites W1983869180 @default.
• W2801542783 cites W1985360203 @default.
• W2801542783 cites W1994944757 @default.
• W2801542783 cites W1998999442 @default.
• W2801542783 cites W2006180313 @default.
• W2801542783 cites W2012482772 @default.
• W2801542783 cites W2016307195 @default.
• W2801542783 cites W2017639101 @default.
• W2801542783 cites W2017757826 @default.
• W2801542783 cites W2023396759 @default.
• W2801542783 cites W2029859343 @default.
• W2801542783 cites W2032257515 @default.
• W2801542783 cites W2036336104 @default.
• W2801542783 cites W2039432666 @default.
• W2801542783 cites W2051521314 @default.
• W2801542783 cites W2057803369 @default.
• W2801542783 cites W2065301075 @default.
• W2801542783 cites W2065821100 @default.
• W2801542783 cites W2084961113 @default.
• W2801542783 cites W2090678639 @default.
• W2801542783 cites W2099494625 @default.
• W2801542783 cites W2101774914 @default.
• W2801542783 cites W2103713166 @default.
• W2801542783 cites W2110188566 @default.
• W2801542783 cites W2114931493 @default.
• W2801542783 cites W2116054757 @default.
• W2801542783 cites W2117394085 @default.
• W2801542783 cites W2118635451 @default.
• W2801542783 cites W2119448875 @default.
• W2801542783 cites W2131000806 @default.
• W2801542783 cites W2135220034 @default.
• W2801542783 cites W2151364453 @default.
• W2801542783 cites W2160232076 @default.
• W2801542783 cites W2162289757 @default.
• W2801542783 cites W2162486568 @default.
• W2801542783 cites W2163254448 @default.
• W2801542783 cites W2163773475 @default.
• W2801542783 cites W2223764430 @default.
• W2801542783 cites W2233068617 @default.
• W2801542783 cites W2260861831 @default.
• W2801542783 cites W2289301112 @default.
• W2801542783 cites W2312213880 @default.
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