DataSheet_1_Coral reef carbonate accretion rates track stable gradients in seawater carbonate chemistry across the U.S. Pacific Islands.pdf

The U.S. Pacific Islands span a dramatic natural gradient in climate and oceanographic conditions, and benthic community states vary significantly across the region’s coral reefs. Here we leverage a decade of integrated ecosystem monitoring data from American Samoa, the Mariana Archipelago, the main...

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Bibliographic Details
Main Authors: Hannah C. Barkley, Thomas A. Oliver, Ariel A. Halperin, Noah V. Pomeroy, Joy N. Smith, Rebecca M. Weible, Charles W. Young, Courtney S. Couch, Russell E. Brainard, Jennifer C. Samson
Format: Dataset
Language:unknown
Published: 2022
Subjects:
Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
coral reefs
carbonate chemistry
ocean acidification
carbonate accretion
U.S. Pacific
climate change
reef monitoring
Pacific
Ocean acidification
Online Access:https://doi.org/10.3389/fmars.2022.991685.s001
https://figshare.com/articles/dataset/DataSheet_1_Coral_reef_carbonate_accretion_rates_track_stable_gradients_in_seawater_carbonate_chemistry_across_the_U_S_Pacific_Islands_pdf/21615696
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Summary:The U.S. Pacific Islands span a dramatic natural gradient in climate and oceanographic conditions, and benthic community states vary significantly across the region’s coral reefs. Here we leverage a decade of integrated ecosystem monitoring data from American Samoa, the Mariana Archipelago, the main and Northwestern Hawaiian Islands, and the U.S. Pacific Remote Island Areas to evaluate coral reef community structure and reef processes across a strong natural gradient in pH and aragonite saturation state (Ω ar ). We assess spatial patterns and temporal trends in carbonate chemistry measured in situ at 37 islands and atolls between 2010 and 2019, and evaluate the relationship between long-term mean Ω ar and benthic community cover and composition (benthic cover, coral genera, coral morphology) and reef process (net calcium carbonate accretion rates). We find that net carbonate accretion rates demonstrate significant sensitivity to declining Ω ar , while most benthic ecological metrics show fewer direct responses to lower-Ω ar conditions. These results indicate that metrics of coral reef net carbonate accretion provide a critical tool for monitoring the long-term impacts of ocean acidification that may not be visible by assessing benthic cover and composition alone. The perspectives gained from our long-term, in situ, and co-located coral reef environmental and ecological data sets provide unique insights into effective monitoring practices to identify potential for reef resilience to future ocean acidification and inform effective ecosystem-based management strategies under 21st century global change.

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