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References (66)
-
D. Danckwerts, C. McQuaid, A. Jaeger, G. Mcgregor, R. Dwight, M. Corre, S. Jaquemet (2014)
Biomass consumption by breeding seabirds in the western Indian Ocean: indirect interactions with fisheries and implications for managementIces Journal of Marine Science, 71
-
H. Wickham, Mara Averick, Jennifer Bryan, Winston Chang, Lucy McGowan, Romain François, Garrett Grolemund, Alex Hayes, Lionel Henry, J. Hester, M. Kuhn, Thomas Pedersen, Evan Miller, S. Bache, K. Müller, Jeroen Ooms, David Robinson, D. Seidel, Vitalie Spinu, Kohske Takahashi, Davis Vaughan, Claus Wilke, Kara Woo, Hiroaki Yutani (2019)
Welcome to the TidyverseJ. Open Source Softw., 4
-
L. Soanes, R. Thomas, M. Bolton (2012)
Evaluation of field and analytical methods for estimating the population size of burrow-nesting seabirds from playback surveysBird Study, 59
-
M. Driessen, P. Jarman, S. Troy, S. Callander (2017)
Animal detections vary among commonly used camera trap modelsWildlife Research, 44
-
O. Chastel (2008)
Influence of reproductive success on breeding frequency in four southern petrelsIbis, 137
-
X. Otero, S. Peña-Lastra, A. Pérez-Alberti, T. Ferreira, M. Huerta-Diaz (2018)
Seabird colonies as important global drivers in the nitrogen and phosphorus cyclesNature Communications, 9
-
(1980)
A survey of burrow‐nesting petrels at Macquarie Island based upon remains left by predators -
S. Hamilton (1998)
Determining burrow occupancy, fledging success and land‐based threats to mainland and near‐shore island sooty shearwater (Puffinus griseus) coloniesNew Zealand Journal of Zoology, 25
-
M. Kuhn (2008)
Building Predictive Models in R Using the caret PackageJournal of Statistical Software, 28
-
Ç. Şekercioğlu (2006)
Increasing awareness of avian ecological function.Trends in ecology & evolution, 21 8
-
M. Schulz, S. Robinson, R. Gales (2005)
Breeding of the Grey Petrel (Procellaria cinerea) on Macquarie Island: population size and nesting habitatEmu - Austral Ornithology, 105
-
Johannes Fischer, I. Debski, G. Taylor, H. Wittmer (2020)
Assessing the suitability of non-invasive methods to monitorinterspecific interactions and breeding biology of the South Georgian diving petrel (Pelecanoides georgicus) -
C. Randler, Nadine Kalb (2018)
Distance and size matters: A comparison of six wildlife camera traps and their usefulness for wild birdsEcology and Evolution, 8
-
Oliver Wearn, Paul Glover-Kapfer (2019)
Snap happy: camera traps are an effective sampling tool when compared with alternative methodsRoyal Society Open Science, 6
-
E. Bonnaud, K. Bourgeois, E. Vidal, J. Legrand, M. Corre (2009)
How can the Yelkouan shearwater survive feral cat predation? A meta-population structure as a solution?Population Ecology, 51
-
Thierry Chaurand, H. Weimerskirch (1994)
The regular alternation of short and long foraging trips in the blue petrel Halobaena caerulea: a previously undescribed strategy of food provisioning in a pelagic seabirdJournal of Animal Ecology, 63
-
(2017)
Ultra?compact trail camera: user manual -
A. Sequeira, G. Hays, D. Sims, V. Eguíluz, Jorge Rodríguez, M. Heupel, R. Harcourt, H. Calich, N. Queiroz, D. Costa, J. Fernández-Gracia, L. Ferreira, S. Goldsworthy, M. Hindell, M. Lea, M. Meekan, A. Pagano, S. Shaffer, J. Reisser, M. Thums, M. Weise, C. Duarte (2019)
Overhauling Ocean Spatial Planning to Improve Marine Megafauna ConservationFrontiers in Marine Science
-
M.J. Anderson (2001)
A new method for non?parametric multivariate analysis of variance, 26
-
A. Whitehead, P. Lyver, C. Jones, P. Bellingham, Catriona MacLeod, M. Coleman, B. Karl, K. Drew, D. Pairman, A. Gormley, R. Duncan (2014)
Establishing accurate baseline estimates of breeding populations of a burrowing seabird, the grey-faced petrel (Pterodroma macroptera gouldi) in New ZealandBiological Conservation, 169
-
(2019)
Identifying animal species -
S. Lê, J. Josse, François Husson (2008)
FactoMineR: An R Package for Multivariate AnalysisJournal of Statistical Software, 25
-
N. Ratcliffe, D. Vaughan, C. Whyte, M. Shepherd (1998)
Development of playback census methods for Storm Petrels Hydrobates pelagicusBird Study, 45
-
J.P. Croxall, C. Ricketts, P.A. Prince (1984)
Seabird energetics -
K. Springer (2016)
Methodology and challenges of a complex multi-species eradication in the sub-Antarctic and immediate effects of invasive species removal.New Zealand Journal of Ecology, 40
-
C. Southwell, L. Emmerson (2015)
Remotely-operating camera network expands Antarctic seabird observations of key breeding parameters for ecosystem monitoring and managementJournal for Nature Conservation, 23
-
(1984)
Breeding, distribution and status -
N. Carlile, D. Priddel, T. Reid, P. Fullagar (2019)
Flesh-footed shearwater decline on Lord Howe: Rebuttal to Lavers et al. 2019Global Ecology and Conservation
-
S. Berrow (2000)
The use of acoustics to monitor burrow-nesting white-chinned petrels Procellaria aequinoctialis at Bird Island, South GeorgiaPolar Biology, 23
-
P. Lyver, S. Hamilton, M. McKenzie, I. Dickson, T. MDooher, H. Moller (2008)
A burrowscope for examining petrel nests in burrows -
(2019)
Fleshfooted shearwater decline on Lord Howe: Rebuttal to Lavers et al. 2019. Global Ecology and Conservation -
J. Hinke, A. Barbosa, L. Emmerson, T. Hart, Mariana Juáres, M. Korczak‐Abshire, G. Milinevsky, Mercedes Santos, P. Trathan, G. Watters, C. Southwell (2018)
Estimating nest‐level phenology and reproductive success of colonial seabirds using time‐lapse camerasMethods in Ecology and Evolution, 9
-
A. Hill, Alasdair Davies, Peter Prince, Jake Snaddon, C. Doncaster, A. Rogers (2019)
Leveraging conservation action with open‐source hardwareConservation Letters, 12
-
J. Sinclair (1981)
Techniques for observing Subantarctic burrowing petrels at the nestMarine ornithology, 9
-
Adams N. (2009)
1Papers and Proceedings of the Royal Society of Tasmania, 143
-
M. Willi, Ross Pitman, Anabelle Cardoso, Christina Locke, A. Swanson, Amy Boyer, Marten Veldthuis, L. Fortson (2018)
Identifying animal species in camera trap images using deep learning and citizen scienceMethods in Ecology and Evolution, 10
-
(2017)
Hyperfire High Performance Cameras Instruction Manual -
N. Graham, N. Graham, S. Wilson, P. Carr, P. Carr, A. Hoey, S. Jennings, M. MacNeil (2018)
Seabirds enhance coral reef productivity and functioning in the absence of invasive ratsNature, 559
-
Airam Rodríguez, J. Arcos, V. Bretagnolle, M. Dias, N. Holmes, M. Louzao, J. Provencher, A. Raine, F. Ramírez, B. Rodríguez, Robert Ronconi, R. Taylor, E. Bonnaud, Stephanie Borrelle, V. Cortés, S. Descamps, V. Friesen, M. Genovart, A. Hedd, P. Hodum, G. Humphries, M. Corre, C. Lebarbenchon, Rob Martin, E. Melvin, W. Montevecchi, P. Pinet, I. Pollet, R. Ramos, J. Russell, P. Ryan, A. Sanz‐Aguilar, D. Spatz, M. Travers, S. Votier, R. Wanless, E. Woehler, A. Chiaradia (2019)
Future Directions in Conservation Research on Petrels and ShearwatersFrontiers in Marine Science
-
Barrett R.T. (2006)
1145ICES Journal of Marine Science, 63
-
(1984)
Breeding , distribution and status of burrow - nesting petrels at Macqaurie Island -
(2005)
Guidelines for Using the IUCN Red List Categories and Criteria -
J. Croxall, C. Ricketts, P. Prince (1984)
Impact of Seabirds on Marine Resources, Especially Krill, of South Georgia Waters -
Jeremy Bird, B. Woodworth, R. Fuller, J. Shaw (2020)
Uncertainty in population estimates: a meta-analysis for petrelsbioRxiv
-
J. Lavers, I. Hutton, A. Bond (2019)
Changes in technology and imperfect detection of nest contents impedes reliable estimates of population trends in burrowing seabirdsGlobal Ecology and Conservation
-
Berrow S.D. (2000)
575Polar Biology, 23
-
Marti Anderson (2001)
A new method for non-parametric multivariate analysis of variance in ecology -
(1998)
A burrowscope for examining petrel -
(1985)
Comparative biology of the burrowing petrels of the Crozet Islands -
D. Trowbridge (1874)
Solution of a ProblemAnalyst, 1
-
P. Dyer, G. Hill (1991)
A Solution to the Problem of Determining the Occupancy Status of Wedge-tailed Shearwater Puffinus pacificus BurrowsEmu, 91
-
R. Barrett, G. Chapdelaine, T. Anker‐Nilssen, A. Mosbech, W. Montevecchi, J. Reid, R. Veit (2006)
Seabird numbers and prey consumption in the North AtlanticIces Journal of Marine Science, 63
-
Mark Carey (2009)
The effects of investigator disturbance on procellariiform seabirds: A reviewNew Zealand Journal of Zoology, 36
-
(2016)
Guidelines for designing burrowing petrel surveys to improve population estimate precision -
S. Pendlebury, I. Barnes-Keoghan (2007)
Climate and climate change in the sub-Antarctic -
R. Team (2014)
R: A language and environment for statistical computing.MSOR connections, 1
-
M. Norouzzadeh, Anh Nguyen, M. Kosmala, A. Swanson, M. Palmer, C. Packer, J. Clune (2017)
Automatically identifying, counting, and describing wild animals in camera-trap images with deep learningProceedings of the National Academy of Sciences of the United States of America, 115
-
Anderson M.J. (2001)
32Austral Ecology, 26
-
(2014)
Biomass consumption -
(1981)
Techniques for observing subantarctic -
(2018)
Seabird colonies -
P. Ryan, C. Dorse, G. Hilton (2006)
The conservation status of the spectacled petrel Procellaria conspicillataBiological Conservation, 131
-
Alice Edney, M. Wood (2020)
Applications of digital imaging and analysis in seabird monitoring and researchIbis
-
P. Catry, A. Campos, P. Segurado, Mónica Silva, I. Strange (2003)
Population census and nesting habitat selection of thin-billed prion Pachyptila belcheri on New Island, Falkland IslandsPolar Biology, 26
-
N. Adams (2009)
Climate trends at Macquarie Island and expectations of future climate change in the sub-Antarctic, 143
-
W. Venables, B. Ripley (2010)
Modern Applied Statistics with S
- Publisher
- Wiley
- Copyright
- © 2022 Published by John Wiley & Sons Ltd.
- ISSN
- 2056-3485
- eISSN
- 2056-3485
- DOI
- 10.1002/rse2.235
- Publisher site
- See Article on Publisher Site
Abstract
Burrowing seabirds are important in ecological and conservation terms. Many populations are in flux due to both negative and positive anthropogenic impacts, but their ecology makes measuring changes difficult. Reliably recording key metrics, the proportion of burrows with breeding pairs and the success of breeding attempts requires burrow‐level information on occupancy. We investigated the use of camera traps positioned at burrow entrances for determining the number of breeding pairs in a sample to inform population estimates, and for recording breeding success. The performance of two cameras makes we tested differed markedly, with Spypoint Force 10 trail cameras prone to malfunction while Reconyx HC600 Hyperfire cameras performed well. Nevertheless, both makes yielded season‐long activity patterns for individual burrows, eliminating uncertainty around successful fledging attempts. Dimensionality reduction of activity metrics derived from camera time series suggests breeding and non‐breeding burrows may be identifiable using linear discriminant analyses but sample sizes from our trial were low and group means were only significantly different during certain breeding stages (permutational multivariate analysis of variance: early chick‐rearing f = 3.64, P = 0.06; late chick‐rearing f = 8.28, P = 0.009). Compared with traditional techniques for determining burrow occupancy (e.g. manual burrow inspection and playback of conspecific calls at burrow entrances), camera traps can reduce uncertainty in estimated breeding success and potentially breeding status of burrows. Significant up‐front investment is required in terms of equipment and human resources but for long‐term studies, camera traps may deliver advantages, particularly when unanticipated novel observations and the potential for calibrating traditional methods with cameras are factored in.
Journal
Remote Sensing in Ecology and Conservation – Wiley
Published: Apr 1, 2022
Keywords: Breeding success; burrowing seabird; camera trap; occupancy; seabirds