Shannon Sully scite author profile

Thermal-stress events associated with climate change cause coral bleaching and mortality that threatens coral reefs globally. Yet coral bleaching patterns vary spatially and temporally. Here we synthesize field observations of coral bleaching at 3351 sites in 81 countries from 1998 to 2017 and use a suite of environmental covariates and temperature metrics to analyze bleaching patterns. Coral bleaching was most common in localities experiencing high intensity and high frequency thermal-stress anomalies. However, coral bleaching was significantly less common in localities with a high variance in sea-surface temperature (SST) anomalies. Geographically, the highest probability of coral bleaching occurred at tropical mid-latitude sites (15–20 degrees north and south of the Equator), despite similar thermal stress levels at equatorial sites. In the last decade, the onset of coral bleaching has occurred at significantly higher SSTs (∼0.5 °C) than in the previous decade, suggesting that thermally susceptible genotypes may have declined and/or adapted such that the remaining coral populations now have a higher thermal threshold for bleaching.

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Rapid climate change and no-analog vegetation in lowland Central America during the last 86,000 years

Correa‐Metrio

Bush

Cabrera

et al. 2012

Quaternary Science Reviews

125

109

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A 6900-year history of landscape modification by humans in lowland Amazonia

Bush

Correa‐Metrio

McMichael

et al. 2016

Quaternary Science Reviews

100

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Local conditions magnify coral loss after marine heatwaves

Donovan

Burkepile

Kratochwill

et al. 2021

Science

169

101

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Climate change threatens coral reefs by causing heat stress events that lead to widespread coral bleaching and mortality. Given the global nature of these mass coral mortality events, recent studies argue that mitigating climate change is the only path to conserve coral reefs. Using a global analysis of 223 sites, we show that local stressors act synergistically with climate change to kill corals. Local factors such as high abundance of macroalgae or urchins magnified coral loss in the year after bleaching. Notably, the combined effects of increasing heat stress and macroalgae intensified coral loss. Our results offer an optimistic premise that effective local management, alongside global efforts to mitigate climate change, can help coral reefs survive the Anthropocene.

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Shannon Sully

A global analysis of coral bleaching over the past two decades

Rapid climate change and no-analog vegetation in lowland Central America during the last 86,000 years

A 6900-year history of landscape modification by humans in lowland Amazonia

Local conditions magnify coral loss after marine heatwaves

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