Organic matter diagenesis and precipitation of Mg-rich carbonate and dolomite in modern hypersaline lagoons linked to climate changes

Camila Areias; Cátia Fernandes Barbosa; Anna Paula Soares Cruz; Judith A. McKenzie; Daniel Ariztegui; Timothy Eglinton; Negar Haghipour; Crisógono Vasconcelos; Mónica Sánchez-Román

doi:10.1016/j.gca.2022.09.030

Organic matter diagenesis and precipitation of Mg-rich carbonate and dolomite in modern hypersaline lagoons linked to climate changes

Camila Areias^*, Cátia Fernandes Barbosa, Anna Paula Soares Cruz, Judith A. McKenzie, Daniel Ariztegui, Timothy Eglinton, Negar Haghipour, Crisógono Vasconcelos, Mónica Sánchez-Román

^*Corresponding author for this work

Geology and Geochemistry

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

Abstract

Lipid-biomarkers have been used to reconstruct environmental changes in lacustrine systems on a range of time scales. Lake sediments are excellent archives to apply these tools due to their rapid and amplified response to environmental pressures. For the past thirty years, the hypersaline lagoons of the Rio de Janeiro coastal plain have been studied as natural laboratories for the observation of the biogeochemical processes involved in modern dolomite precipitation. Here, we apply a multiproxy approach to characterize two depositional stages during the Holocene that may have triggered primary dolomite formation in these lagoonal environments. A first stage, with two sub-stages (1A − 6.1 to 4.2 kyr. BP; 1B − 4.2 to ∼3.6 kyr. BP) was deposited during the sea-level rise, with sediments containing an abundance of long-chain n-alkanes with ²H-depleted (δ²H_n_-alk) signatures indicating riverine inputs of terrestrial organic carbon during prevailing wet conditions. A second stage (<∼3.6 kyr. BP), comprising lacustrine facies, was characterized by high amounts of authigenic carbonate precipitates (calcite, Mg-calcite, Ca-dolomite, and dolomite). The carbonates are the result of physico-chemical changes in the water after the isolation of the lagoons from both the Atlantic Ocean and the neighboring Lagoa de Araruama due to a fall in sea level and aridification associated with intensification of the coastal upwelling after 2.2 kyr. BP. The n-alkanes deposited during this phase contain variable proportions of long and short-chain homologues indicating a mixed source of organic matter (terrestrial higher plants and microorganisms), as well as changes in vegetation associated with the driest conditions, inferred from the ²H-enriched n-alkane homologous. These results clearly demonstrate a climatic influence on dolomite formation in coastal hypersaline environments linked to sea-level change and coastal upwelling phenomena. With these observations, we hypothesize that the existence of similar palaeoceanographic and environmental conditions in the geologic past may have triggered the formation of extensive microbial dolomite deposits. This study provides new elements to interpret the formation of massive dolomite deposits in the geological record, for example, along the Late Triassic Tethys margin.

Original language	English
Pages (from-to)	14-32
Number of pages	19
Journal	Geochimica et Cosmochimica Acta
Volume	337
Early online date	29 Sept 2022
DOIs	https://doi.org/10.1016/j.gca.2022.09.030
Publication status	Published - 15 Nov 2022

Bibliographical note

Funding Information:
C.A. thanks the Rio de Janeiro Research Support Foundation (FAPERJ) for funding to support her doctoral studies and the Swiss Government Excellence Scholarship for funding that covered her stay in Switzerland. We also thank Dr. José Carlos Sícoli Seoane, Dr. Daniel Souza dos Santos and Dr. Nicolas Stríkis for their help with the coring operations in the field. We thank Dr. Hendrik Vogel and Dr. Marina Morlock from the Institute of Geological Sciences, University of Bern, for helping with XRF core scanning. We thank Daniel Montluçon for his assistance with the lipid biomarker analysis and Madalina Jaggi for her assistance with the stable isotope measurements. CA also thanks Nayara Dornellas, Daniel Fraçois and Luiz G. de Sá Valle for their invaluable help during fieldwork campaigns. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001“.

Funding Information:
C.A. thanks the Rio de Janeiro Research Support Foundation (FAPERJ) for funding to support her doctoral studies and the Swiss Government Excellence Scholarship for funding that covered her stay in Switzerland. We also thank Dr. José Carlos Sícoli Seoane, Dr. Daniel Souza dos Santos and Dr. Nicolas Stríkis for their help with the coring operations in the field. We thank Dr. Hendrik Vogel and Dr. Marina Morlock from the Institute of Geological Sciences, University of Bern, for helping with XRF core scanning. We thank Daniel Montluçon for his assistance with the lipid biomarker analysis and Madalina Jaggi for her assistance with the stable isotope measurements. CA also thanks Nayara Dornellas, Daniel Fraçois and Luiz G. de Sá Valle for their invaluable help during fieldwork campaigns. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001“.

Publisher Copyright:
© 2022 The Author(s)

Funding

C.A. thanks the Rio de Janeiro Research Support Foundation (FAPERJ) for funding to support her doctoral studies and the Swiss Government Excellence Scholarship for funding that covered her stay in Switzerland. We also thank Dr. José Carlos Sícoli Seoane, Dr. Daniel Souza dos Santos and Dr. Nicolas Stríkis for their help with the coring operations in the field. We thank Dr. Hendrik Vogel and Dr. Marina Morlock from the Institute of Geological Sciences, University of Bern, for helping with XRF core scanning. We thank Daniel Montluçon for his assistance with the lipid biomarker analysis and Madalina Jaggi for her assistance with the stable isotope measurements. CA also thanks Nayara Dornellas, Daniel Fraçois and Luiz G. de Sá Valle for their invaluable help during fieldwork campaigns. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001“. C.A. thanks the Rio de Janeiro Research Support Foundation (FAPERJ) for funding to support her doctoral studies and the Swiss Government Excellence Scholarship for funding that covered her stay in Switzerland. We also thank Dr. José Carlos Sícoli Seoane, Dr. Daniel Souza dos Santos and Dr. Nicolas Stríkis for their help with the coring operations in the field. We thank Dr. Hendrik Vogel and Dr. Marina Morlock from the Institute of Geological Sciences, University of Bern, for helping with XRF core scanning. We thank Daniel Montluçon for his assistance with the lipid biomarker analysis and Madalina Jaggi for her assistance with the stable isotope measurements. CA also thanks Nayara Dornellas, Daniel Fraçois and Luiz G. de Sá Valle for their invaluable help during fieldwork campaigns. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001“.

Keywords

Diagenesis
Lipid Biomarkers
Microbial Dolomite
Stable Isotopes
Upwelling

UN SDGs

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

Access to Document

10.1016/j.gca.2022.09.030

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Cite this

Areias, C., Barbosa, C. F., Cruz, A. P. S., McKenzie, J. A., Ariztegui, D., Eglinton, T., Haghipour, N., Vasconcelos, C., & Sánchez-Román, M. (2022). Organic matter diagenesis and precipitation of Mg-rich carbonate and dolomite in modern hypersaline lagoons linked to climate changes. Geochimica et Cosmochimica Acta, 337, 14-32. https://doi.org/10.1016/j.gca.2022.09.030

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abstract = "Lipid-biomarkers have been used to reconstruct environmental changes in lacustrine systems on a range of time scales. Lake sediments are excellent archives to apply these tools due to their rapid and amplified response to environmental pressures. For the past thirty years, the hypersaline lagoons of the Rio de Janeiro coastal plain have been studied as natural laboratories for the observation of the biogeochemical processes involved in modern dolomite precipitation. Here, we apply a multiproxy approach to characterize two depositional stages during the Holocene that may have triggered primary dolomite formation in these lagoonal environments. A first stage, with two sub-stages (1A − 6.1 to 4.2 kyr. BP; 1B − 4.2 to ∼3.6 kyr. BP) was deposited during the sea-level rise, with sediments containing an abundance of long-chain n-alkanes with 2H-depleted (δ2Hn-alk) signatures indicating riverine inputs of terrestrial organic carbon during prevailing wet conditions. A second stage (<∼3.6 kyr. BP), comprising lacustrine facies, was characterized by high amounts of authigenic carbonate precipitates (calcite, Mg-calcite, Ca-dolomite, and dolomite). The carbonates are the result of physico-chemical changes in the water after the isolation of the lagoons from both the Atlantic Ocean and the neighboring Lagoa de Araruama due to a fall in sea level and aridification associated with intensification of the coastal upwelling after 2.2 kyr. BP. The n-alkanes deposited during this phase contain variable proportions of long and short-chain homologues indicating a mixed source of organic matter (terrestrial higher plants and microorganisms), as well as changes in vegetation associated with the driest conditions, inferred from the 2H-enriched n-alkane homologous. These results clearly demonstrate a climatic influence on dolomite formation in coastal hypersaline environments linked to sea-level change and coastal upwelling phenomena. With these observations, we hypothesize that the existence of similar palaeoceanographic and environmental conditions in the geologic past may have triggered the formation of extensive microbial dolomite deposits. This study provides new elements to interpret the formation of massive dolomite deposits in the geological record, for example, along the Late Triassic Tethys margin.",

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author = "Camila Areias and Barbosa, \{C{\'a}tia Fernandes\} and Cruz, \{Anna Paula Soares\} and McKenzie, \{Judith A.\} and Daniel Ariztegui and Timothy Eglinton and Negar Haghipour and Cris{\'o}gono Vasconcelos and M{\'o}nica S{\'a}nchez-Rom{\'a}n",

note = "Funding Information: C.A. thanks the Rio de Janeiro Research Support Foundation (FAPERJ) for funding to support her doctoral studies and the Swiss Government Excellence Scholarship for funding that covered her stay in Switzerland. We also thank Dr. Jos{\'e} Carlos S{\'i}coli Seoane, Dr. Daniel Souza dos Santos and Dr. Nicolas Str{\'i}kis for their help with the coring operations in the field. We thank Dr. Hendrik Vogel and Dr. Marina Morlock from the Institute of Geological Sciences, University of Bern, for helping with XRF core scanning. We thank Daniel Montlu{\c c}on for his assistance with the lipid biomarker analysis and Madalina Jaggi for her assistance with the stable isotope measurements. CA also thanks Nayara Dornellas, Daniel Fra{\c c}ois and Luiz G. de S{\'a} Valle for their invaluable help during fieldwork campaigns. This study was financed in part by the Coordena{\c c}{\~a}o de Aperfei{\c c}oamento de Pessoal de N{\'i}vel Superior – Brasil (CAPES) – Finance Code 001“. Funding Information: C.A. thanks the Rio de Janeiro Research Support Foundation (FAPERJ) for funding to support her doctoral studies and the Swiss Government Excellence Scholarship for funding that covered her stay in Switzerland. We also thank Dr. Jos{\'e} Carlos S{\'i}coli Seoane, Dr. Daniel Souza dos Santos and Dr. Nicolas Str{\'i}kis for their help with the coring operations in the field. We thank Dr. Hendrik Vogel and Dr. Marina Morlock from the Institute of Geological Sciences, University of Bern, for helping with XRF core scanning. We thank Daniel Montlu{\c c}on for his assistance with the lipid biomarker analysis and Madalina Jaggi for her assistance with the stable isotope measurements. CA also thanks Nayara Dornellas, Daniel Fra{\c c}ois and Luiz G. de S{\'a} Valle for their invaluable help during fieldwork campaigns. This study was financed in part by the Coordena{\c c}{\~a}o de Aperfei{\c c}oamento de Pessoal de N{\'i}vel Superior – Brasil (CAPES) – Finance Code 001“. Publisher Copyright: {\textcopyright} 2022 The Author(s)",

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T1 - Organic matter diagenesis and precipitation of Mg-rich carbonate and dolomite in modern hypersaline lagoons linked to climate changes

AU - Areias, Camila

AU - Barbosa, Cátia Fernandes

AU - Cruz, Anna Paula Soares

AU - McKenzie, Judith A.

AU - Ariztegui, Daniel

AU - Eglinton, Timothy

AU - Haghipour, Negar

AU - Vasconcelos, Crisógono

AU - Sánchez-Román, Mónica

N1 - Funding Information: C.A. thanks the Rio de Janeiro Research Support Foundation (FAPERJ) for funding to support her doctoral studies and the Swiss Government Excellence Scholarship for funding that covered her stay in Switzerland. We also thank Dr. José Carlos Sícoli Seoane, Dr. Daniel Souza dos Santos and Dr. Nicolas Stríkis for their help with the coring operations in the field. We thank Dr. Hendrik Vogel and Dr. Marina Morlock from the Institute of Geological Sciences, University of Bern, for helping with XRF core scanning. We thank Daniel Montluçon for his assistance with the lipid biomarker analysis and Madalina Jaggi for her assistance with the stable isotope measurements. CA also thanks Nayara Dornellas, Daniel Fraçois and Luiz G. de Sá Valle for their invaluable help during fieldwork campaigns. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001“. Funding Information: C.A. thanks the Rio de Janeiro Research Support Foundation (FAPERJ) for funding to support her doctoral studies and the Swiss Government Excellence Scholarship for funding that covered her stay in Switzerland. We also thank Dr. José Carlos Sícoli Seoane, Dr. Daniel Souza dos Santos and Dr. Nicolas Stríkis for their help with the coring operations in the field. We thank Dr. Hendrik Vogel and Dr. Marina Morlock from the Institute of Geological Sciences, University of Bern, for helping with XRF core scanning. We thank Daniel Montluçon for his assistance with the lipid biomarker analysis and Madalina Jaggi for her assistance with the stable isotope measurements. CA also thanks Nayara Dornellas, Daniel Fraçois and Luiz G. de Sá Valle for their invaluable help during fieldwork campaigns. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001“. Publisher Copyright: © 2022 The Author(s)

PY - 2022/11/15

Y1 - 2022/11/15

N2 - Lipid-biomarkers have been used to reconstruct environmental changes in lacustrine systems on a range of time scales. Lake sediments are excellent archives to apply these tools due to their rapid and amplified response to environmental pressures. For the past thirty years, the hypersaline lagoons of the Rio de Janeiro coastal plain have been studied as natural laboratories for the observation of the biogeochemical processes involved in modern dolomite precipitation. Here, we apply a multiproxy approach to characterize two depositional stages during the Holocene that may have triggered primary dolomite formation in these lagoonal environments. A first stage, with two sub-stages (1A − 6.1 to 4.2 kyr. BP; 1B − 4.2 to ∼3.6 kyr. BP) was deposited during the sea-level rise, with sediments containing an abundance of long-chain n-alkanes with 2H-depleted (δ2Hn-alk) signatures indicating riverine inputs of terrestrial organic carbon during prevailing wet conditions. A second stage (<∼3.6 kyr. BP), comprising lacustrine facies, was characterized by high amounts of authigenic carbonate precipitates (calcite, Mg-calcite, Ca-dolomite, and dolomite). The carbonates are the result of physico-chemical changes in the water after the isolation of the lagoons from both the Atlantic Ocean and the neighboring Lagoa de Araruama due to a fall in sea level and aridification associated with intensification of the coastal upwelling after 2.2 kyr. BP. The n-alkanes deposited during this phase contain variable proportions of long and short-chain homologues indicating a mixed source of organic matter (terrestrial higher plants and microorganisms), as well as changes in vegetation associated with the driest conditions, inferred from the 2H-enriched n-alkane homologous. These results clearly demonstrate a climatic influence on dolomite formation in coastal hypersaline environments linked to sea-level change and coastal upwelling phenomena. With these observations, we hypothesize that the existence of similar palaeoceanographic and environmental conditions in the geologic past may have triggered the formation of extensive microbial dolomite deposits. This study provides new elements to interpret the formation of massive dolomite deposits in the geological record, for example, along the Late Triassic Tethys margin.

AB - Lipid-biomarkers have been used to reconstruct environmental changes in lacustrine systems on a range of time scales. Lake sediments are excellent archives to apply these tools due to their rapid and amplified response to environmental pressures. For the past thirty years, the hypersaline lagoons of the Rio de Janeiro coastal plain have been studied as natural laboratories for the observation of the biogeochemical processes involved in modern dolomite precipitation. Here, we apply a multiproxy approach to characterize two depositional stages during the Holocene that may have triggered primary dolomite formation in these lagoonal environments. A first stage, with two sub-stages (1A − 6.1 to 4.2 kyr. BP; 1B − 4.2 to ∼3.6 kyr. BP) was deposited during the sea-level rise, with sediments containing an abundance of long-chain n-alkanes with 2H-depleted (δ2Hn-alk) signatures indicating riverine inputs of terrestrial organic carbon during prevailing wet conditions. A second stage (<∼3.6 kyr. BP), comprising lacustrine facies, was characterized by high amounts of authigenic carbonate precipitates (calcite, Mg-calcite, Ca-dolomite, and dolomite). The carbonates are the result of physico-chemical changes in the water after the isolation of the lagoons from both the Atlantic Ocean and the neighboring Lagoa de Araruama due to a fall in sea level and aridification associated with intensification of the coastal upwelling after 2.2 kyr. BP. The n-alkanes deposited during this phase contain variable proportions of long and short-chain homologues indicating a mixed source of organic matter (terrestrial higher plants and microorganisms), as well as changes in vegetation associated with the driest conditions, inferred from the 2H-enriched n-alkane homologous. These results clearly demonstrate a climatic influence on dolomite formation in coastal hypersaline environments linked to sea-level change and coastal upwelling phenomena. With these observations, we hypothesize that the existence of similar palaeoceanographic and environmental conditions in the geologic past may have triggered the formation of extensive microbial dolomite deposits. This study provides new elements to interpret the formation of massive dolomite deposits in the geological record, for example, along the Late Triassic Tethys margin.

KW - Diagenesis

KW - Lipid Biomarkers

KW - Microbial Dolomite

KW - Stable Isotopes

KW - Upwelling

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M3 - Article

AN - SCOPUS:85139337752

SN - 0016-7037

VL - 337

SP - 14

EP - 32

JO - Geochimica et Cosmochimica Acta

JF - Geochimica et Cosmochimica Acta

ER -

Organic matter diagenesis and precipitation of Mg-rich carbonate and dolomite in modern hypersaline lagoons linked to climate changes

Abstract

Bibliographical note

Funding

Keywords

UN SDGs

Access to Document

Persistent URL (handle)

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