|Title||Limited coral mortality following acute thermal stress and widespread bleaching on Palmyra Atoll, central Pacific|
|Publication Type||Journal Article|
|Year of Publication||2019|
|Authors||Fox M.D, Carter A.L, Edwards C.B, Takeshita Y, Johnson M.D, Petrovic V., Amir C.G, Sala E, Sandin SA, Smith JE|
|Type of Article||Article|
|Keywords||climate change; Coral bleaching; coral reefs; coralline algae; Crustose; disturbance; El Nino; el-nino; Herbivory; Marine & Freshwater Biology; montipora capitata; patterns; recovery; reef; resilience; settlement; temperature; warming; winners|
During 2015-2016, an El Nino and associated warm water event caused widespread coral bleaching across the equatorial Pacific. Here, we combine 8 yr of benthic monitoring data from permanent photoquadrats with remotely sensed and in situ temperature measurements to assess the impact of the warming event on benthic communities at Palmyra Atoll. We quantified bleaching prevalence across two distinct reef habitats using the best available data. On the fore reef (similar to 10 m depth), we quantified bleaching severity within 100-200 m(2) large-area plots using the custom visualization and analysis software, Viscore. On the reef terrace (similar to 5 m depth), we used 95 focal colonies across three species that have been monitored annually since 2014. The 2015-2016 warm water event was the most extreme such event recorded on Palmyra in the past several decades with a maximum cumulative heat stress (degree heating weeks) of 11.9 degrees C-weeks. On the fore reef, 90% of live coral cover exhibited some degree of bleaching (32% severe bleaching). On the shallow reef terrace, bleaching was observed in 93% of the focal colonies across all species. Overall, coral cover declined 9% on the fore reef from 2014 to 2017, whereas coral cover did not change on the terrace. These contrasting results may be associated with typical daily temperature ranges on the terrace that are three times greater than on the fore reef. Permanent photoquadrats showed that turf algae initially colonized skeletons of recently dead corals but transitioned to crustose coralline algae within a year. Collectively, our study emphasizes that comprehensive monitoring of benthic communities over time combined with in situ temperature data can provide taxonomically precise trajectories of community change during and following thermal stress.