Home > Research > Publications & Outputs > Unifying Coral Reef States Through Space and Ti...

Research

Electronic data

Links

Text available via DOI:

View graph of relations

Unifying Coral Reef States Through Space and Time Reveals a Changing Ecosystem

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Published

Standard

Unifying Coral Reef States Through Space and Time Reveals a Changing Ecosystem. / Brandl, Simon J.; Carlot, Jérémy; Stuart‐Smith, Rick D. et al.
In: Global Ecology and Biogeography, Vol. 33, No. 12, e13926, 31.12.2024.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Brandl, SJ, Carlot, J, Stuart‐Smith, RD, Keith, SA, Graham, NAJ, Edgar, GJ, Wicquart, J, Wilson, SK, Karkarey, R, Donovan, MK, Arias‐Gonzalez, JE, Arthur, R, Bigot, L, Exton, DA, Goetze, J, Hoey, AS, Holmes, T, Maréchal, JP, Mouillot, D, Ross, CL, Wickel, J, Adjeroud, M & Parravicini, V 2024, 'Unifying Coral Reef States Through Space and Time Reveals a Changing Ecosystem', Global Ecology and Biogeography, vol. 33, no. 12, e13926. https://doi.org/10.1111/geb.13926

APA

Brandl, SJ., Carlot, J., Stuart‐Smith, RD., Keith, SA., Graham, NA. J., Edgar, GJ., Wicquart, J., Wilson, SK., Karkarey, R., Donovan, MK., Arias‐Gonzalez, JE., Arthur, R., Bigot, L., Exton, DA., Goetze, J., Hoey, AS., Holmes, T., Maréchal, JP., Mouillot, D., ... Parravicini, V. (2024). Unifying Coral Reef States Through Space and Time Reveals a Changing Ecosystem. Global Ecology and Biogeography, 33(12), Article e13926. https://doi.org/10.1111/geb.13926

Vancouver

Brandl SJ, Carlot J, Stuart‐Smith RD, Keith SA, Graham NAJ, Edgar GJ et al. Unifying Coral Reef States Through Space and Time Reveals a Changing Ecosystem. Global Ecology and Biogeography. 2024 Dec 31;33(12):e13926. Epub 2024 Oct 17. doi: 10.1111/geb.13926

Author

Brandl, Simon J. ; Carlot, Jérémy ; Stuart‐Smith, Rick D. et al. / Unifying Coral Reef States Through Space and Time Reveals a Changing Ecosystem. In: Global Ecology and Biogeography. 2024 ; Vol. 33, No. 12.

Bibtex

@article{369ff9b3c70d4e06845fdbb3633af06c,
title = "Unifying Coral Reef States Through Space and Time Reveals a Changing Ecosystem",
abstract = "AimEcological state shifts that alter the structure and function of entire ecosystems are a concerning consequence of human impact. Yet, when, where and why discrete ecological states emerge remains difficult to predict and monitor, especially in high‐diversity systems. We sought to quantify state shifts and their drivers through space and time in the most ecologically complex marine ecosystem: tropical coral reefs.LocationWorldwide.Time Period1987–2019.Major Taxa StudiedCoral reef communities.MethodsUsing a global dataset of 3375 coral reef surveys, along with 13 time series datasets ranging between 1987 and 2019, we applied a novel double‐dichotomy approach to classify coral reefs into four simplified and discrete states based on the relative contributions of corals versus algae to benthic cover and small‐bodied versus large‐bodied fishes to fish standing stock. We then examined state shifts considering a range of spatial predictors and tested whether states have shifted directionally over time, and the nature of the most common transitions.ResultsWe show that geographic, environmental and anthropogenic context fundamentally shapes coral reef states at the local scale, which explains disparities among case studies, and stakes out critical baseline expectations for regional management efforts. We also reveal clear multi‐decadal state shifts on coral reefs: over time, systems dominated by reef‐building corals and small‐bodied, planktivorous fishes tend to have been replaced with reefs characterised by algae and larger‐bodied fishes.Main ConclusionsOur results suggest a previously unrecognised transition from systems that harness external subsidies through small‐bodied consumers associated with structurally complex live corals, to herbivore‐dominated systems with stronger bottom‐up dynamics. Overall, the partitioning of complex reef ecosystems into a small suite of discrete ecological states suggests that spatial context‐dependency, shifting baselines and changes in reef functioning are crucial considerations for coral reef management in the 21st century.",
author = "Simon J. Brandl and J{\'e}r{\'e}my Carlot and Rick D. Stuart‐Smith and Sally A. Keith and Nicholas A. J. Graham and Graham J. Edgar and J{\'e}r{\'e}my Wicquart and Shaun K. Wilson and Rucha Karkarey and Mary K. Donovan and Jesus E. Arias‐Gonzalez and Rohan Arthur and Lionel Bigot and Dan A. Exton and Jordan Goetze and Andrew S. Hoey and Thomas Holmes and Jean‐Philippe Mar{\'e}chal and David Mouillot and Claire L. Ross and Julien Wickel and Mehdi Adjeroud and Valeriano Parravicini",
year = "2024",
month = dec,
day = "31",
doi = "10.1111/geb.13926",
language = "English",
volume = "33",
journal = "Global Ecology and Biogeography",
issn = "1466-822X",
publisher = "Blackwell Publishing Ltd",
number = "12",

}

RIS

TY - JOUR

T1 - Unifying Coral Reef States Through Space and Time Reveals a Changing Ecosystem

AU - Brandl, Simon J.

AU - Carlot, Jérémy

AU - Stuart‐Smith, Rick D.

AU - Keith, Sally A.

AU - Graham, Nicholas A. J.

AU - Edgar, Graham J.

AU - Wicquart, Jérémy

AU - Wilson, Shaun K.

AU - Karkarey, Rucha

AU - Donovan, Mary K.

AU - Arias‐Gonzalez, Jesus E.

AU - Arthur, Rohan

AU - Bigot, Lionel

AU - Exton, Dan A.

AU - Goetze, Jordan

AU - Hoey, Andrew S.

AU - Holmes, Thomas

AU - Maréchal, Jean‐Philippe

AU - Mouillot, David

AU - Ross, Claire L.

AU - Wickel, Julien

AU - Adjeroud, Mehdi

AU - Parravicini, Valeriano

PY - 2024/12/31

Y1 - 2024/12/31

N2 - AimEcological state shifts that alter the structure and function of entire ecosystems are a concerning consequence of human impact. Yet, when, where and why discrete ecological states emerge remains difficult to predict and monitor, especially in high‐diversity systems. We sought to quantify state shifts and their drivers through space and time in the most ecologically complex marine ecosystem: tropical coral reefs.LocationWorldwide.Time Period1987–2019.Major Taxa StudiedCoral reef communities.MethodsUsing a global dataset of 3375 coral reef surveys, along with 13 time series datasets ranging between 1987 and 2019, we applied a novel double‐dichotomy approach to classify coral reefs into four simplified and discrete states based on the relative contributions of corals versus algae to benthic cover and small‐bodied versus large‐bodied fishes to fish standing stock. We then examined state shifts considering a range of spatial predictors and tested whether states have shifted directionally over time, and the nature of the most common transitions.ResultsWe show that geographic, environmental and anthropogenic context fundamentally shapes coral reef states at the local scale, which explains disparities among case studies, and stakes out critical baseline expectations for regional management efforts. We also reveal clear multi‐decadal state shifts on coral reefs: over time, systems dominated by reef‐building corals and small‐bodied, planktivorous fishes tend to have been replaced with reefs characterised by algae and larger‐bodied fishes.Main ConclusionsOur results suggest a previously unrecognised transition from systems that harness external subsidies through small‐bodied consumers associated with structurally complex live corals, to herbivore‐dominated systems with stronger bottom‐up dynamics. Overall, the partitioning of complex reef ecosystems into a small suite of discrete ecological states suggests that spatial context‐dependency, shifting baselines and changes in reef functioning are crucial considerations for coral reef management in the 21st century.

AB - AimEcological state shifts that alter the structure and function of entire ecosystems are a concerning consequence of human impact. Yet, when, where and why discrete ecological states emerge remains difficult to predict and monitor, especially in high‐diversity systems. We sought to quantify state shifts and their drivers through space and time in the most ecologically complex marine ecosystem: tropical coral reefs.LocationWorldwide.Time Period1987–2019.Major Taxa StudiedCoral reef communities.MethodsUsing a global dataset of 3375 coral reef surveys, along with 13 time series datasets ranging between 1987 and 2019, we applied a novel double‐dichotomy approach to classify coral reefs into four simplified and discrete states based on the relative contributions of corals versus algae to benthic cover and small‐bodied versus large‐bodied fishes to fish standing stock. We then examined state shifts considering a range of spatial predictors and tested whether states have shifted directionally over time, and the nature of the most common transitions.ResultsWe show that geographic, environmental and anthropogenic context fundamentally shapes coral reef states at the local scale, which explains disparities among case studies, and stakes out critical baseline expectations for regional management efforts. We also reveal clear multi‐decadal state shifts on coral reefs: over time, systems dominated by reef‐building corals and small‐bodied, planktivorous fishes tend to have been replaced with reefs characterised by algae and larger‐bodied fishes.Main ConclusionsOur results suggest a previously unrecognised transition from systems that harness external subsidies through small‐bodied consumers associated with structurally complex live corals, to herbivore‐dominated systems with stronger bottom‐up dynamics. Overall, the partitioning of complex reef ecosystems into a small suite of discrete ecological states suggests that spatial context‐dependency, shifting baselines and changes in reef functioning are crucial considerations for coral reef management in the 21st century.

U2 - 10.1111/geb.13926

DO - 10.1111/geb.13926

M3 - Journal article

VL - 33

JO - Global Ecology and Biogeography

JF - Global Ecology and Biogeography

SN - 1466-822X

IS - 12

M1 - e13926

ER -