Abstract
Coral reefs protect islands, coastal areas, and their inhabitants from storm waves and provide essential goods and services to millions of people worldwide. Yet contemporary rates of ocean warming and local disturbances are jeopardizing the reef-building capacity of coral reefs to keep up with rapid rates of sea-level rise. This study compared the reef-building capacity of shallow-water habitats at 142 sites across a potential thermal-stress gradient in the tropical Pacific Ocean. We sought to determine the extent to which habitat differences and environmental variables potentially affect rates of net carbonate production. In general, outer-exposed reefs and lagoonal-patch reefs had higher rates of net carbonate production than nearshore reefs. The study found that thermal anomalies, particularly the intensity of thermal-stress events, play a significant role in reducing net carbonate production—evident as a diminishing trend of net carbonate production from the western to the central tropical Pacific Ocean. The results also showed a latent spatial effect along the same gradient, not explained by thermal stress, suggesting that reefs in the western tropical Pacific Ocean are potentially enhanced by the proximity of reefs in the Coral Triangle—an effect that diminishes with increasing distance and isolation.
Highlights
Coral reefs reduce storm-driven wave energy by over 95% [1] protecting island and coastal inhabitants and provide other essential goods and services to millions of people worldwide [2]
The reefs of Kiritimati in the central Pacific Ocean have experienced seven thermal stress events since 1982 the most extreme of which was from June to November in 2015 when the degree heating weeks were consistently above 15, and sea surface temperatures (SSTs) were up to 5 ̊C above average (Fig 2)
These thermal-stress events are reflected in the rates of net carbonate production estimated on the reefs from 2017 to 2019
Summary
Coral reefs reduce storm-driven wave energy by over 95% [1] protecting island and coastal inhabitants and provide other essential goods and services to millions of people worldwide [2]. After more than 5000 years of relative sea-level stability [3, 4], coral reefs worldwide are currently experiencing rapid rates of sea-level rise [5, 6]. Healthy reefs tracked sea-level fluctuations [7], but recent increases in thermal-stress events [8, 9] and local disturbances [10] are reducing the capacity of coral reefs to keep up with sea-level rise [11, 12]. One of the central questions today is: where will coral reefs be able to accumulate enough carbonate to keep up with the rate of sea-level rise? This question is relevant as the average rate of sea-level rise is expected to increase from 2 mm to 9 mm a year into the 21st century [13,14,15]. One of the central questions today is: where will coral reefs be able to accumulate enough carbonate to keep up with the rate of sea-level rise? This question is relevant as the average rate of sea-level rise is expected to increase from 2 mm to 9 mm a year into the 21st century [13,14,15].
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
