Iodine-to-calcium ratios in deep-sea scleractinian and bamboo corals

The distribution of dissolved iodine in seawater is sensitive to multiple biogeochemical cycles, including those of nitrogen and oxygen. The iodine-to-calcium ratio (I/Ca) of marine carbonates, such as bulk carbonate or foraminifera, has emerged as a potential proxy for changes in past seawater oxyg...

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Bibliographic Details
Published in:Frontiers in Marine Science
Main Authors: Sun, Yun-Ju, Robinson, Laura F, Parkinson, Ian J, Stewart, Joseph A, Lu, Wanyi, Hardisty, Dalton S, Liu, Qian, Kershaw, James, LaVigne, Michèle, Horner, Tristan J
Format: Article in Journal/Newspaper
Language:English
Published: 2023
Subjects:
Earth Sciences > Oceanography
Seawater oxygen1
Iodine2
Deep-sea coral3
Scleractinian coral4
Bamboo coral5
Deep sea
Corals
Seawater
Biogeochemistry
Biological control
Deep water
Geochemistry
Hypoxia
Oxygenation
Archives
Mineralogy
Iodates
Oceans
Museums
Foraminifera
Radiometric dating
Carbonates
Calcium
Iodine
Biogeochemical cycles
Marine invertebrates
Oxidation
Oxygen
Archives & records
Biogeochemical cycle
Southern Ocean
Pacific
North Atlantic
Online Access:https://hdl.handle.net/1983/1bac35c3-4b3d-4e69-919f-fb3022ce4fd4
https://research-information.bris.ac.uk/en/publications/1bac35c3-4b3d-4e69-919f-fb3022ce4fd4
https://doi.org/10.3389/fmars.2023.1264380
https://bris.idm.oclc.org/login?url=https://www.proquest.com/scholarly-journals/iodine-calcium-ratios-deep-sea-scleractinian/docview/2886738384/se-2?accountid=9730
https://media.proquest.com/media/hms/PFT/1/oxIAW?_a=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%3D%3D&_s=3TTSC4bXE4FtjrhIe38nKF3UZKU%3D
https://bris.on.worldcat.org/atoztitles/link?sid=ProQ:&issn=&volume=&issue=&title=Frontiers+in+Marine+Science&spage=&date=2023-11-07&atitle=Iodine-to-calcium+ratios+in+deep-sea+scleractinian+and+bamboo+corals&au=Sun,+Yun-Ju%3BRobinson,+Laura+F%3BParkinson,+Ian+J%3BStewart,+Joseph+A%3BLu,+Wanyi%3BHardisty,+Dalton+S%3BLiu,+Qian%3BKershaw,+James%3BLaVigne,+Mich%C3%A8le%3BHorner,+Tristan+J&id=doi:10.3389%2Ffmars.2023.1264380
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Summary:The distribution of dissolved iodine in seawater is sensitive to multiple biogeochemical cycles, including those of nitrogen and oxygen. The iodine-to-calcium ratio (I/Ca) of marine carbonates, such as bulk carbonate or foraminifera, has emerged as a potential proxy for changes in past seawater oxygenation. However, the utility of the I/Ca proxy in deep-sea corals, natural archives of seawater chemistry with wide spatial coverage and radiometric dating potential, remains unexplored. Here, we present the first I/Ca data obtained from modern deep-sea corals, specifically scleractinian and bamboo corals, collected from the Atlantic, Eastern Pacific, and Southern Oceans, encompassing a wide range of seawater oxygen concentrations (10–280 μmol/kg). In contrast to thermodynamic predictions, we observe higher I/Ca ratios in aragonitic corals (scleractinian) compared to calcitic corals (bamboo). This observation suggests a strong biological control during iodate incorporation into deep-sea coral skeletons. For the majority of scleractinian corals, I/Ca exhibits a covariation with local seawater iodate concentrations, which is closely related to seawater oxygen content. Scleractinian corals also exhibit notably lower I/Ca below a seawater oxygen threshold of approximately 160 μmol/kg. In contrast, no significant differences in I/Ca are found among bamboo corals across the range of oxygen concentrations encountered (15–240 μmol/kg). In the North Atlantic, several hydrographic factors, such as temperature and/or salinity, may additionally affect coral I/Ca. Our results highlight the potential of I/Ca ratios in deep-sea scleractinian corals to serve as an indicator of past seawater iodate concentrations, providing valuable insights into historical seawater oxygen levels.

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