Extreme temperature events will drive coral decline in the Coral Triangle

Extreme temperature events will drive coral decline in the Coral Triangle

In light of rapid environmental change, quantifying the contribution of regional‐ and local‐scale drivers of coral persistence is necessary to characterize fully the resilience of coral reef systems. To assess multiscale responses to thermal perturbation of corals in the Coral Triangle (CT), we deve...

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Veröffentlicht in:Global change biology 2020-04, Vol.26 (4), p.2120-2133
Hauptverfasser: McManus, Lisa C., Vasconcelos, Vítor V., Levin, Simon A., Thompson, Diane M., Kleypas, Joan A., Castruccio, Frederic S., Curchitser, Enrique N., Watson, James R.
Format: Artikel
Sprache:eng
Schlagworte:
Algae
Anomalies
Bleaching
climate change
Climate variability
coral persistence
Coral reefs
Corals
Dispersal
El Niño
Environmental changes
Larvae
metacommunity
Multiscale analysis
Perturbation
Probability theory
resilience
Sea surface
Sea surface temperature
seascape
Sensitivity
Species extinction
Survival
Temperature
Thermal stress
Variability
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container_end_page 2133
container_issue 4
container_start_page 2120
container_title Global change biology
container_volume 26
creator McManus, Lisa C.
Vasconcelos, Vítor V.
Levin, Simon A.
Thompson, Diane M.
Kleypas, Joan A.
Castruccio, Frederic S.
Curchitser, Enrique N.
Watson, James R.
description In light of rapid environmental change, quantifying the contribution of regional‐ and local‐scale drivers of coral persistence is necessary to characterize fully the resilience of coral reef systems. To assess multiscale responses to thermal perturbation of corals in the Coral Triangle (CT), we developed a spatially explicit metacommunity model with coral–algal competition, including seasonal larval dispersal and external spatiotemporal forcing. We tested coral sensitivity in 2,083 reefs across the CT region and surrounding areas under potential future temperature regimes, with and without interannual climate variability, exploring a range of 0.5–2.0°C overall increase in temperature in the system by 2054. We found that among future projections, reef survival probability and mean percent coral cover over time were largely determined by the presence or absence of interannual sea surface temperature (SST) extremes as well as absolute temperature increase. Overall, reefs that experienced SST time series that were filtered to remove interannual variability had approximately double the chance of survival than reefs subjected to unfiltered SST. By the end of the forecast period, the inclusion of thermal anomalies was equivalent to an increase of at least 0.5°C in SST projections without anomalies. Change in percent coral cover varied widely across the region within temperature scenarios, with some reefs experiencing local extinction while others remaining relatively unchanged. Sink strength and current thermal stress threshold were found to be significant drivers of these patterns, highlighting the importance of processes that underlie larval connectivity and bleaching sensitivity in coral networks. To assess multiscale responses to thermal perturbation of corals in the Coral Triangle (CT), we developed a metacommunity model with coral‐algal competition, seasonal larval dispersal and external spatio‐temporal forcing. We tested coral sensitivity in 2,083 reefs across the CT region under potential future temperature regimes, with and without interannual climate variability. By the end of the forecast period, the inclusion of interannual thermal anomalies was equivalent to an increase of at least 0.5°C in temperature projections without anomalies.
doi_str_mv 10.1111/gcb.14972
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To assess multiscale responses to thermal perturbation of corals in the Coral Triangle (CT), we developed a spatially explicit metacommunity model with coral–algal competition, including seasonal larval dispersal and external spatiotemporal forcing. We tested coral sensitivity in 2,083 reefs across the CT region and surrounding areas under potential future temperature regimes, with and without interannual climate variability, exploring a range of 0.5–2.0°C overall increase in temperature in the system by 2054. We found that among future projections, reef survival probability and mean percent coral cover over time were largely determined by the presence or absence of interannual sea surface temperature (SST) extremes as well as absolute temperature increase. Overall, reefs that experienced SST time series that were filtered to remove interannual variability had approximately double the chance of survival than reefs subjected to unfiltered SST. By the end of the forecast period, the inclusion of thermal anomalies was equivalent to an increase of at least 0.5°C in SST projections without anomalies. Change in percent coral cover varied widely across the region within temperature scenarios, with some reefs experiencing local extinction while others remaining relatively unchanged. Sink strength and current thermal stress threshold were found to be significant drivers of these patterns, highlighting the importance of processes that underlie larval connectivity and bleaching sensitivity in coral networks. To assess multiscale responses to thermal perturbation of corals in the Coral Triangle (CT), we developed a metacommunity model with coral‐algal competition, seasonal larval dispersal and external spatio‐temporal forcing. We tested coral sensitivity in 2,083 reefs across the CT region under potential future temperature regimes, with and without interannual climate variability. 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subjects Algae
Anomalies
Bleaching
climate change
Climate variability
coral persistence
Coral reefs
Corals
Dispersal
El Niño
Environmental changes
Larvae
metacommunity
Multiscale analysis
Perturbation
Probability theory
resilience
Sea surface
Sea surface temperature
seascape
Sensitivity
Species extinction
Survival
Temperature
Thermal stress
Variability
title Extreme temperature events will drive coral decline in the Coral Triangle
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