Sensitivity of δ 13 C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach

Biologging technologies have revolutionised our understanding of the foraging ecology and life history traits of marine predators, allowing for high resolution information about location, and in some cases, foraging behaviour of wild animals. At the same time, stable isotope ecologists have independ...

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Published in:Journal of Experimental Marine Biology and Ecology
Main Authors: Carpenter-Kling, Tegan, Pistorius, Pierre, Connan, Maëlle, Reisinger, Ryan, Magozzi, Sarah, Trueman, Clive
Format: Article in Journal/Newspaper
Language:English
Published: 2019
Subjects:
Antarctic
Antarc*
Giant Petrels
Marion Island
Online Access:https://eprints.soton.ac.uk/429897/
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spelling ftsouthampton:oai:eprints.soton.ac.uk:429897 2023-07-30T03:58:22+02:00 Sensitivity of δ 13 C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach Carpenter-Kling, Tegan Pistorius, Pierre Connan, Maëlle Reisinger, Ryan Magozzi, Sarah Trueman, Clive 2019-03 https://eprints.soton.ac.uk/429897/ English eng Carpenter-Kling, Tegan, Pistorius, Pierre, Connan, Maëlle, Reisinger, Ryan, Magozzi, Sarah and Trueman, Clive (2019) Sensitivity of δ13C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach. Journal of Experimental Marine Biology and Ecology, 512, 12-21. (doi:10.1016/j.jembe.2018.12.007 <http://dx.doi.org/10.1016/j.jembe.2018.12.007>). Article PeerReviewed 2019 ftsouthampton https://doi.org/10.1016/j.jembe.2018.12.007 2023-07-09T22:28:55Z Biologging technologies have revolutionised our understanding of the foraging ecology and life history traits of marine predators, allowing for high resolution information about location, and in some cases, foraging behaviour of wild animals. At the same time, stable isotope ecologists have independently developed methods to infer location and foraging ecology (trophic geography). To date, relatively few studies have combined these two approaches, despite the potential wealth of complementary information. In marine systems, spatial and trophic information are coded in the isotopic composition of carbon and nitrogen in animal tissues, but interpretation of isotope values is limited by both the lack of reference maps (isoscapes) needed to relate the isotopic composition of an animal's tissues to a location, and the relatively large number of variables that could influence tissue isotope compositions. Simulation modelling can help to interpret measured tissue isotope compositions of migratory animals in the context of spatio-temporally dynamic isotopic baselines. Here, we couple individual-based movement models with global marine isotope models to explore the sensitivity of tissue δ 13 C values to a range of extrinsic (environmental) and intrinsic (behavioural, physiological) drivers. We use in-silico experiments to simulate isotopic compositions expected for birds exhibiting different movement and foraging behaviours and compare these simulated data to isotopic data recovered from biologger-equipped female northern giant petrels Macronectes halli incubating eggs on sub-Antarctic Marion Island. Our simulations suggest that in the studied system, time is a strong driver of isotopic variance. Accordingly, this implies that caution should be used when comparing δ 13 C values of marine predators’ tissues between seasons and years. We show how an in-silico experimental approach can be used to explore the sensitivity of animal tissue isotopic compositions to complex and often interacting drivers. Appreciation of the ... Article in Journal/Newspaper Antarc* Antarctic Giant Petrels Marion Island University of Southampton: e-Prints Soton Antarctic Journal of Experimental Marine Biology and Ecology 512 12 21
institution Open Polar
collection University of Southampton: e-Prints Soton
op_collection_id ftsouthampton
language English
description Biologging technologies have revolutionised our understanding of the foraging ecology and life history traits of marine predators, allowing for high resolution information about location, and in some cases, foraging behaviour of wild animals. At the same time, stable isotope ecologists have independently developed methods to infer location and foraging ecology (trophic geography). To date, relatively few studies have combined these two approaches, despite the potential wealth of complementary information. In marine systems, spatial and trophic information are coded in the isotopic composition of carbon and nitrogen in animal tissues, but interpretation of isotope values is limited by both the lack of reference maps (isoscapes) needed to relate the isotopic composition of an animal's tissues to a location, and the relatively large number of variables that could influence tissue isotope compositions. Simulation modelling can help to interpret measured tissue isotope compositions of migratory animals in the context of spatio-temporally dynamic isotopic baselines. Here, we couple individual-based movement models with global marine isotope models to explore the sensitivity of tissue δ 13 C values to a range of extrinsic (environmental) and intrinsic (behavioural, physiological) drivers. We use in-silico experiments to simulate isotopic compositions expected for birds exhibiting different movement and foraging behaviours and compare these simulated data to isotopic data recovered from biologger-equipped female northern giant petrels Macronectes halli incubating eggs on sub-Antarctic Marion Island. Our simulations suggest that in the studied system, time is a strong driver of isotopic variance. Accordingly, this implies that caution should be used when comparing δ 13 C values of marine predators’ tissues between seasons and years. We show how an in-silico experimental approach can be used to explore the sensitivity of animal tissue isotopic compositions to complex and often interacting drivers. Appreciation of the ...
format Article in Journal/Newspaper
author Carpenter-Kling, Tegan
Pistorius, Pierre
Connan, Maëlle
Reisinger, Ryan
Magozzi, Sarah
Trueman, Clive
spellingShingle Carpenter-Kling, Tegan
Pistorius, Pierre
Connan, Maëlle
Reisinger, Ryan
Magozzi, Sarah
Trueman, Clive
Sensitivity of δ 13 C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach
author_facet Carpenter-Kling, Tegan
Pistorius, Pierre
Connan, Maëlle
Reisinger, Ryan
Magozzi, Sarah
Trueman, Clive
author_sort Carpenter-Kling, Tegan
title Sensitivity of δ 13 C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach
title_short Sensitivity of δ 13 C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach
title_full Sensitivity of δ 13 C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach
title_fullStr Sensitivity of δ 13 C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach
title_full_unstemmed Sensitivity of δ 13 C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach
title_sort sensitivity of δ 13 c values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach
publishDate 2019
url https://eprints.soton.ac.uk/429897/
geographic Antarctic
geographic_facet Antarctic
genre Antarc*
Antarctic
Giant Petrels
Marion Island
genre_facet Antarc*
Antarctic
Giant Petrels
Marion Island
op_relation Carpenter-Kling, Tegan, Pistorius, Pierre, Connan, Maëlle, Reisinger, Ryan, Magozzi, Sarah and Trueman, Clive (2019) Sensitivity of δ13C values of seabird tissues to combined spatial, temporal and ecological drivers: a simulation approach. Journal of Experimental Marine Biology and Ecology, 512, 12-21. (doi:10.1016/j.jembe.2018.12.007 <http://dx.doi.org/10.1016/j.jembe.2018.12.007>).
op_doi https://doi.org/10.1016/j.jembe.2018.12.007
container_title Journal of Experimental Marine Biology and Ecology
container_volume 512
container_start_page 12
op_container_end_page 21
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