Carbonate dissolution fluxes in deep-sea sediments as determined from in situ porewater profiles in a transect across the saturation horizon

Creators: Cetiner, Jaclyn E. P.¹; Berelson, William M.¹; Rollins, Nick E.¹; Liu, Xuewu²; Pavia, Frank J.³; Waldeck, Anna R.⁴; Dong, Sijia³; Fleger, Kalla²; Barnhart, Holly A.³; Quinan, Matthew¹; Wani, Rucha P.¹; Rafter, Patrick A.⁵; Jacobson, Andrew D.⁴; Byrne, Robert H.²; Adkins, Jess F.³

1. University of Southern California
2. University of South Florida
3. California Institute of Technology
4. Northwestern University
5. University of California, Irvine

Abstract

Despite their importance for long-term climate regulation, the rates and mechanisms of seafloor carbonate dissolution are poorly understood, especially with respect to calcite saturation and the role of sedimentary metabolic CO₂ production. Here, we present results from an in situ porewater sampler deployed at the Cocos Ridge in the eastern equatorial Pacific, where we examine seafloor carbonate dissolution in locations with bottom water Ω_calcite ranging from 1.0 to 0.84 (1600–3200 m). With cm-scale resolution from the sediment–water interface to 35 cm, we present porewater profiles of total alkalinity, pH, dissolved inorganic carbon (DIC), δ¹³C of DIC, Ω_calcite, [Mn], [Ca], and [Sr], as well as solid phase porosity, % CaCO₃, and % organic C. These profiles provide evidence that deep-sea sedimentary carbonate dissolution occurs via sediment-side control, wherein dissolution is dominated by sedimentary processes rather than strictly bottom water saturation state. We estimate dissolution fluxes using three independent approaches: alkalinity fluxes, δ¹³C of DIC combined with DIC fluxes, and [Ca] fluxes. We report seafloor dissolution fluxes with uncertainties < 38 %: 40 ± 15, 98 ± 20, 100 ± 32, and 89 ± 27 μmol CaCO₃/m²/day at sites 3200, 2900, 2700, and 1600 m deep, respectively. The magnitude of dissolution fluxes is a function of bottom water saturation state (Ω_calcite), bottom water dissolved oxygen, and sedimentary CaCO₃ content, but not correlated with any of these parameters independently. We observe dissolution occurring at all stations, including where bottom water is saturated with respect to calcite, and present evidence that this occurs through respiration-driven dissolution within the sediment. At all sites, porewater Ω_calcite decreases below bottom water values before increasing toward saturation deeper in the sediment. Using the δ¹³C of DIC, we partition the DIC fluxes across the sediment–water interface and find 21–48 % of DIC is sourced from CaCO₃ dissolution, with the remainder sourced from organic matter respiration. We present a sedimentary mass balance, assembled with dissolution rates and mass accumulation rates obtained through Δ¹⁴C of foraminiferal calcite, and calculate CaCO₃ burial efficiencies between 2 and 67 %, inversely correlating with water depth. Our results also provide evidence that net chemical erosion of 5,000––10,000 year old carbonate is occurring at the deepest site. Aerobic organic C respiration coupled with sedimentary CaCO₃ dissolution, as documented here, will provide more alkalinity to bottom waters than from undersaturation-driven dissolution alone. This process can neutralize anthropogenic CO₂ at the seafloor in a larger range of saturation states than previously estimated.

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Acknowledgement

This work was supported by NSF Ocean Acidification (OCE-1834475 to WMB and JFA). JEPC thanks USC Earth Sciences for additional PhD funding for this work. We thank Aaron Celestian (Natural History Museum of Los Angeles) and Menglong Zhang (Nanjing University) for assistance with XRD mineralogy. We thank Per Hall (University of Gothenburg) and his group for help with design questions regarding syringe type, and the USC Machine Shop, specifically Seth Wieman, for their design and construction efforts on the porewater sampler. Metal analysis was performed at the Northwestern University Quantitative Bio-element Imaging Center. We thank Doug Hammond and Naomi Levine (USC) for helpful comments and insights on the manuscript. We thank the editors of GCA, as well as Andy Dale and two anonymous reviewers, whose thoughtful questions and comments greatly improved the manuscript. Thank you to Emma Johnson for assistance with the porewater sampler during the CDSIP 2021 cruise. Thank you to the captain and crew of the R/V Yellowfin at the Southern California Marine Institute for helping us test our equipment many, many times. The science party, captain, and crew of R/V Sally Ride SR2113 cruise were indispensable in the collection of the data presented here, and we sincerely thank them all.

Funding

This work was supported by NSF Ocean Acidification (OCE-1834475 to WMB and JFA). JEPC thanks USC Earth Sciences for additional PhD funding for this work.

Contributions

Jaclyn E.P. Cetiner: Writing – original draft, Visualization, Methodology, Investigation, Formal analysis, Data curation, Conceptualization. William M. Berelson: Writing – review & editing, Supervision, Resources, Methodology, Investigation, Funding acquisition, Conceptualization. Nick E. Rollins: Writing – review & editing, Methodology, Data curation. Xuewu Liu: Writing – review & editing, Methodology, Data curation. Frank J. Pavia: Writing – review & editing, Methodology, Investigation, Data curation. Anna R. Waldeck: Writing – review & editing, Methodology, Data curation. Sijia Dong: Writing – review & editing, Methodology, Investigation, Data curation. Kalla Fleger: Writing – review & editing, Methodology, Data curation. Holly A. Barnhart: Writing – review & editing, Methodology, Data curation. Matthew Quinan: Writing – review & editing, Data curation. Rucha P. Wani: Writing – review & editing, Visualization. Patrick A. Rafter: Writing – review & editing, Methodology, Data curation. Andrew D. Jacobson: Writing – review & editing, Supervision, Resources. Robert H. Byrne: Writing – review & editing, Supervision, Resources. Jess F. Adkins: Writing – review & editing, Supervision, Resources, Investigation, Funding acquisition, Conceptualization.

Data Availability

Data are stored in the BCO-DMO database in the following four datasets:

Porewater: Cetiner, J. E., Berelson, W. M., Rollins, N. E., Liu, X., Pavia, F. J., Waldeck, A., Dong, S., Fleger, K., Barnhart, H., Quinan, M., Wani, R., Jacobson, A., Byrne, R., Adkins, J. F. (2024) In situ porewater data from the Cocos Ridge (Eastern Equatorial Pacific) acquired during cruise SR2113 between November - December 2021. Biological and Chemical Oceanography Data Management Office (BCO-DMO). (Version 1) Version Date 2024-06-21. https://demo.bco-dmo.org/dataset/925487

Solid phase: Cetiner, J. E., Berelson, W. M., Rollins, N. E., Dong, S., Adkins, J. F. (2024) Solid phase measurements of sediment cores from the Cocos Ridge (Eastern Equatorial Pacific) acquired during cruise SR2113 between November - December 2021. Biological and Chemical Oceanography Data Management Office (BCO-DMO). (Version 1) Version Date 2024-06-20. https://demo.bco-dmo.org/dataset/925132

Water column: Cetiner, J. E., Berelson, W. M., Rollins, N. E., Liu, X., Dong, S., Fleger, K., Barnhart, H., Byrne, R., Adkins, J. F., Sanchez Noguera, C. (2024) Water column data from the Cocos Ridge (Eastern Equatorial Pacific) acquired during cruise SR2113 between November - December 2021. Biological and Chemical Oceanography Data Management Office (BCO-DMO). (Version 1) Version Date 2024-06-20. https://demo.bco-dmo.org/dataset/925367

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