Laboratory Observation of the Buffering Effect of Aragonite Dissolution at the Seafloor

H. van de Mortel; L. Delaigue; M.P. Humphreys; J.J. Middelburg; S. Ossebaar; K. Bakker; J.P. Trabucho Alexandre; A.W.E. van Leeuwen ‐ Tolboom; M. Wolthers; O. Sulpis

doi:10.1029/2023JG007581

Laboratory Observation of the Buffering Effect of Aragonite Dissolution at the Seafloor

H. van de Mortel^*, L. Delaigue, M.P. Humphreys, J.J. Middelburg, S. Ossebaar, K. Bakker, J.P. Trabucho Alexandre, A.W.E. van Leeuwen ‐ Tolboom, M. Wolthers, O. Sulpis^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Carbon dioxide entering and acidifying the ocean can be neutralized by the dissolution of calcium carbonate, which is mainly found in two mineral forms. Calcite is the more stable form and is often found in deep-sea sediments, whilst aragonite is more soluble and therefore rarely preserved. Recent research shows aragonite may account for a much larger portion of marine calcium carbonate export to the ocean interior via the biological pump than previously thought, and that aragonite does reach the deep sea and seafloor despite rarely being buried. If aragonite is present and dissolving at the seafloor it will raise local pH and calcium and carbonate concentrations, potentially enough to inhibit calcite dissolution, representing a deep-sea, carbonate version of galvanization. Here, we test this hypothesis by simulating aragonite dissolution at the sediment-water interface in the laboratory and measuring its effects on pH using microsensors. We show that the addition of aragonite to calcite sediment, overlain by seawater undersaturated with respect to both minerals, results in an unchanged alkalinity flux out of the dissolving sediment, suggesting a decrease the net dissolution rate of calcite. In combination with a diagenetic model, we show that aragonite dissolution can suppress calcite dissolution in the top millimeters of the seabed, locally leading to calcite precipitation within 1 day. Future research efforts should quantify this galvanization effect in situ, as this process may represent an important component of the marine carbon cycle, assigning a key role to aragonite producers in controlling ocean alkalinity and preserving climatic archives.

Original language	English
Article number	e2023JG007581
Number of pages	20
Journal	Journal of Geophysical Research: Biogeosciences
Volume	129
Issue number	2
DOIs	https://doi.org/10.1029/2023JG007581
Publication status	Published - Feb 2024

Bibliographical note

Publisher Copyright:
© 2024. The Authors.

Funding

We thank Peter Kraal for his assistance at NIOZ, Geert-Jan Brummer for providing calcite sand and pteropods and Furu Mienis for providing cold-water coral samples. We thank Thom Claessen for his help in the UU Geolab. We thank Cecile Hilgen for her transportation services from the UU to NIOZ. We thank Anton Tramper from NIOZ Yerseke for lending and assisting with the Visisens TD system. We thank Olga Zygadlowska for explaining the Unisense software and helpful advice, as well as Caroline Slomp for lending the microprofiling system. This research was supported by the Netherlands Organisation for Scientific Research (NWO-XS Grant OCENW.XS3.059 and NWO-VENI Grant VI.Veni.212.086 to O.S.) and the Netherlands Earth System Science Center. This project has received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant agreement 819588) to M. Wolthers. This research was supported by the Netherlands Organisation for Scientific Research (NWO‐XS Grant OCENW.XS3.059 and NWO‐VENI Grant VI.Veni.212.086 to O.S.) and the Netherlands Earth System Science Center. This project has received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant agreement 819588) to M. Wolthers.

Funders	Funder number
NWO-Veni
NWO-XS
NWO‐VENI	VI.Veni.212.086
NWO‐XS	OCENW.XS3.059
UU Geolab
European Research Council
Nederlandse Organisatie voor Wetenschappelijk Onderzoek
Horizon 2020	819588
Koninklijk Nederlands Instituut voor Onderzoek der Zee
Netherlands Earth System Science Centre

Keywords

carbon cycling
marine geochemistry

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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JGR Biogeosciences - 2024 - Mortel - Laboratory Observation of the Buffering Effect of Aragonite Dissolution at theFinal published version, 1.18 MBLicence: CC BY

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van de Mortel, H., Delaigue, L., Humphreys, M. P., Middelburg, J. J., Ossebaar, S., Bakker, K., Trabucho Alexandre, J. P., van Leeuwen ‐ Tolboom, A. W. E., Wolthers, M., & Sulpis, O. (2024). Laboratory Observation of the Buffering Effect of Aragonite Dissolution at the Seafloor. Journal of Geophysical Research: Biogeosciences, 129(2), Article e2023JG007581. https://doi.org/10.1029/2023JG007581

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title = "Laboratory Observation of the Buffering Effect of Aragonite Dissolution at the Seafloor",

abstract = "Carbon dioxide entering and acidifying the ocean can be neutralized by the dissolution of calcium carbonate, which is mainly found in two mineral forms. Calcite is the more stable form and is often found in deep-sea sediments, whilst aragonite is more soluble and therefore rarely preserved. Recent research shows aragonite may account for a much larger portion of marine calcium carbonate export to the ocean interior via the biological pump than previously thought, and that aragonite does reach the deep sea and seafloor despite rarely being buried. If aragonite is present and dissolving at the seafloor it will raise local pH and calcium and carbonate concentrations, potentially enough to inhibit calcite dissolution, representing a deep-sea, carbonate version of galvanization. Here, we test this hypothesis by simulating aragonite dissolution at the sediment-water interface in the laboratory and measuring its effects on pH using microsensors. We show that the addition of aragonite to calcite sediment, overlain by seawater undersaturated with respect to both minerals, results in an unchanged alkalinity flux out of the dissolving sediment, suggesting a decrease the net dissolution rate of calcite. In combination with a diagenetic model, we show that aragonite dissolution can suppress calcite dissolution in the top millimeters of the seabed, locally leading to calcite precipitation within 1 day. Future research efforts should quantify this galvanization effect in situ, as this process may represent an important component of the marine carbon cycle, assigning a key role to aragonite producers in controlling ocean alkalinity and preserving climatic archives.",

keywords = "carbon cycling, marine geochemistry",

author = "{van de Mortel}, H. and L. Delaigue and M.P. Humphreys and J.J. Middelburg and S. Ossebaar and K. Bakker and {Trabucho Alexandre}, J.P. and {van Leeuwen ‐ Tolboom}, A.W.E. and M. Wolthers and O. Sulpis",

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doi = "10.1029/2023JG007581",

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van de Mortel, H, Delaigue, L, Humphreys, MP, Middelburg, JJ, Ossebaar, S, Bakker, K, Trabucho Alexandre, JP , van Leeuwen ‐ Tolboom, AWE , Wolthers, M & Sulpis, O 2024, 'Laboratory Observation of the Buffering Effect of Aragonite Dissolution at the Seafloor', Journal of Geophysical Research: Biogeosciences, vol. 129, no. 2, e2023JG007581. https://doi.org/10.1029/2023JG007581

TY - JOUR

T1 - Laboratory Observation of the Buffering Effect of Aragonite Dissolution at the Seafloor

AU - van de Mortel, H.

AU - Delaigue, L.

AU - Humphreys, M.P.

AU - Middelburg, J.J.

AU - Ossebaar, S.

AU - Bakker, K.

AU - Trabucho Alexandre, J.P.

AU - van Leeuwen ‐ Tolboom, A.W.E.

AU - Wolthers, M.

AU - Sulpis, O.

PY - 2024/2

Y1 - 2024/2

N2 - Carbon dioxide entering and acidifying the ocean can be neutralized by the dissolution of calcium carbonate, which is mainly found in two mineral forms. Calcite is the more stable form and is often found in deep-sea sediments, whilst aragonite is more soluble and therefore rarely preserved. Recent research shows aragonite may account for a much larger portion of marine calcium carbonate export to the ocean interior via the biological pump than previously thought, and that aragonite does reach the deep sea and seafloor despite rarely being buried. If aragonite is present and dissolving at the seafloor it will raise local pH and calcium and carbonate concentrations, potentially enough to inhibit calcite dissolution, representing a deep-sea, carbonate version of galvanization. Here, we test this hypothesis by simulating aragonite dissolution at the sediment-water interface in the laboratory and measuring its effects on pH using microsensors. We show that the addition of aragonite to calcite sediment, overlain by seawater undersaturated with respect to both minerals, results in an unchanged alkalinity flux out of the dissolving sediment, suggesting a decrease the net dissolution rate of calcite. In combination with a diagenetic model, we show that aragonite dissolution can suppress calcite dissolution in the top millimeters of the seabed, locally leading to calcite precipitation within 1 day. Future research efforts should quantify this galvanization effect in situ, as this process may represent an important component of the marine carbon cycle, assigning a key role to aragonite producers in controlling ocean alkalinity and preserving climatic archives.

AB - Carbon dioxide entering and acidifying the ocean can be neutralized by the dissolution of calcium carbonate, which is mainly found in two mineral forms. Calcite is the more stable form and is often found in deep-sea sediments, whilst aragonite is more soluble and therefore rarely preserved. Recent research shows aragonite may account for a much larger portion of marine calcium carbonate export to the ocean interior via the biological pump than previously thought, and that aragonite does reach the deep sea and seafloor despite rarely being buried. If aragonite is present and dissolving at the seafloor it will raise local pH and calcium and carbonate concentrations, potentially enough to inhibit calcite dissolution, representing a deep-sea, carbonate version of galvanization. Here, we test this hypothesis by simulating aragonite dissolution at the sediment-water interface in the laboratory and measuring its effects on pH using microsensors. We show that the addition of aragonite to calcite sediment, overlain by seawater undersaturated with respect to both minerals, results in an unchanged alkalinity flux out of the dissolving sediment, suggesting a decrease the net dissolution rate of calcite. In combination with a diagenetic model, we show that aragonite dissolution can suppress calcite dissolution in the top millimeters of the seabed, locally leading to calcite precipitation within 1 day. Future research efforts should quantify this galvanization effect in situ, as this process may represent an important component of the marine carbon cycle, assigning a key role to aragonite producers in controlling ocean alkalinity and preserving climatic archives.

KW - carbon cycling

KW - marine geochemistry

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U2 - 10.1029/2023JG007581

DO - 10.1029/2023JG007581

M3 - Article

SN - 2169-8953

VL - 129

JO - Journal of Geophysical Research: Biogeosciences

JF - Journal of Geophysical Research: Biogeosciences

IS - 2

M1 - e2023JG007581

ER -

Laboratory Observation of the Buffering Effect of Aragonite Dissolution at the Seafloor

Abstract

Bibliographical note

Funding

Keywords

UN SDGs

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