A global ocean opal ballasting–silicate relationship

B. B. Cael; C. Mark Moore; Joe Guest; Tereza Jarníková; Colleen B. Mouw; Chris Bowler; Edward Mawji; Stephanie A. Henson; Corinne Le Quéré

doi:10.1029/2024GL110225

A global ocean opal ballasting–silicate relationship

B. B. Cael, C. Mark Moore, Joe Guest, Tereza Jarníková, Colleen B. Mouw, Chris Bowler, Edward Mawji, Stephanie A. Henson, Corinne Le Quéré

School of Environmental Sciences

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Abstract

Opal and calcium carbonate are thought to regulate the biological pump's transfer of organic carbon to the deep ocean. A global sediment trap database exhibits large regional variations in the organic carbon flux associated with opal flux. These variations are well-explained by upper ocean silicate concentrations, with high opal ‘ballasting’ in the silicate-deplete tropical Atlantic Ocean, and low ballasting in the silicate-rich Southern Ocean. A plausible, testable hypothesis is that opal ballasting varies because diatoms grow thicker frustules where silicate concentrations are higher, carrying less organic carbon per unit opal. The observed pattern does not fully emerge in an advanced ocean biogeochemical model when diatom silicification is represented using a single global parameterization as a function of silicate and iron. Our results suggest a need for improving understanding of currently modeled processes and/or considering additional parameterizations to capture the links between elemental cycles and future biological pump changes.

Original language	English
Article number	e2024GL110225
Journal	Geophysical Research Letters
Volume	51
Issue number	19
DOIs	https://doi.org/10.1029/2024GL110225
Publication status	Published - 16 Oct 2024

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Geophysical Research Letters - 2024 - Cael - A Global Ocean Opal Ballasting Silicate RelationshipFinal published version, 1.01 MBLicence: CC BY

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@article{03d683e27c3444f797d6cc03a55414f7,

title = "A global ocean opal ballasting–silicate relationship",

abstract = "Opal and calcium carbonate are thought to regulate the biological pump's transfer of organic carbon to the deep ocean. A global sediment trap database exhibits large regional variations in the organic carbon flux associated with opal flux. These variations are well-explained by upper ocean silicate concentrations, with high opal {\textquoteleft}ballasting{\textquoteright} in the silicate-deplete tropical Atlantic Ocean, and low ballasting in the silicate-rich Southern Ocean. A plausible, testable hypothesis is that opal ballasting varies because diatoms grow thicker frustules where silicate concentrations are higher, carrying less organic carbon per unit opal. The observed pattern does not fully emerge in an advanced ocean biogeochemical model when diatom silicification is represented using a single global parameterization as a function of silicate and iron. Our results suggest a need for improving understanding of currently modeled processes and/or considering additional parameterizations to capture the links between elemental cycles and future biological pump changes.",

author = "Cael, {B. B.} and Moore, {C. Mark} and Joe Guest and Tereza Jarn{\'i}kov{\'a} and Mouw, {Colleen B.} and Chris Bowler and Edward Mawji and Henson, {Stephanie A.} and {Le Qu{\'e}r{\'e}}, Corinne",

note = "Data Availability Statement: The data used for this study are available from (Garcia et al., 2019; Mouw et al., 2016) and the code for their analysis is available at (Cael, 2024). Numerical model documentation and output are available at (Buitenhuis et al., 2023). Funding information: Cael, Henson and Jarn{\'i}kov{\'a} acknowledge support by the National Environmental Resarch Council (NERC) Grant NE/T010622/1 CELOS (Constraining the EvoLution of the southern Ocean carbon Sink). Cael, Guest, Henson, and Le Qu{\'e}r{\'e} acknowledge support from Schmidt Sciences via the Virtual Earth System Research Institute project CALIPSO. Le Qu{\'e}r{\'e} acknowledges support from the NERC Grant NE/V011103/1 Marine Frontiers. Guest acknowledges support from the Royal Society Grant RP.R1.191063. Bowler acknowldges support from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Diatomic; grant agreement No. 835067).",

year = "2024",

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doi = "10.1029/2024GL110225",

language = "English",

volume = "51",

journal = "Geophysical Research Letters",

issn = "0094-8276",

publisher = "American Geophysical Union",

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T1 - A global ocean opal ballasting–silicate relationship

AU - Cael, B. B.

AU - Moore, C. Mark

AU - Guest, Joe

AU - Jarníková, Tereza

AU - Mouw, Colleen B.

AU - Bowler, Chris

AU - Mawji, Edward

AU - Henson, Stephanie A.

AU - Le Quéré, Corinne

N1 - Data Availability Statement: The data used for this study are available from (Garcia et al., 2019; Mouw et al., 2016) and the code for their analysis is available at (Cael, 2024). Numerical model documentation and output are available at (Buitenhuis et al., 2023). Funding information: Cael, Henson and Jarníková acknowledge support by the National Environmental Resarch Council (NERC) Grant NE/T010622/1 CELOS (Constraining the EvoLution of the southern Ocean carbon Sink). Cael, Guest, Henson, and Le Quéré acknowledge support from Schmidt Sciences via the Virtual Earth System Research Institute project CALIPSO. Le Quéré acknowledges support from the NERC Grant NE/V011103/1 Marine Frontiers. Guest acknowledges support from the Royal Society Grant RP.R1.191063. Bowler acknowldges support from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Diatomic; grant agreement No. 835067).

PY - 2024/10/16

Y1 - 2024/10/16

N2 - Opal and calcium carbonate are thought to regulate the biological pump's transfer of organic carbon to the deep ocean. A global sediment trap database exhibits large regional variations in the organic carbon flux associated with opal flux. These variations are well-explained by upper ocean silicate concentrations, with high opal ‘ballasting’ in the silicate-deplete tropical Atlantic Ocean, and low ballasting in the silicate-rich Southern Ocean. A plausible, testable hypothesis is that opal ballasting varies because diatoms grow thicker frustules where silicate concentrations are higher, carrying less organic carbon per unit opal. The observed pattern does not fully emerge in an advanced ocean biogeochemical model when diatom silicification is represented using a single global parameterization as a function of silicate and iron. Our results suggest a need for improving understanding of currently modeled processes and/or considering additional parameterizations to capture the links between elemental cycles and future biological pump changes.

AB - Opal and calcium carbonate are thought to regulate the biological pump's transfer of organic carbon to the deep ocean. A global sediment trap database exhibits large regional variations in the organic carbon flux associated with opal flux. These variations are well-explained by upper ocean silicate concentrations, with high opal ‘ballasting’ in the silicate-deplete tropical Atlantic Ocean, and low ballasting in the silicate-rich Southern Ocean. A plausible, testable hypothesis is that opal ballasting varies because diatoms grow thicker frustules where silicate concentrations are higher, carrying less organic carbon per unit opal. The observed pattern does not fully emerge in an advanced ocean biogeochemical model when diatom silicification is represented using a single global parameterization as a function of silicate and iron. Our results suggest a need for improving understanding of currently modeled processes and/or considering additional parameterizations to capture the links between elemental cycles and future biological pump changes.

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U2 - 10.1029/2024GL110225

DO - 10.1029/2024GL110225

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VL - 51

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 19

M1 - e2024GL110225

ER -

A global ocean opal ballasting–silicate relationship

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