Microbially induced potassium enrichment in Paleoproterozoic shales and implications for reverse weathering on early Earth

Jérémie Aubineau; Abderrazak El Albani; Andrey Bekker; Andrea Somogyi; Olabode M. Bankole; Roberto Macchiarelli; Alain Meunier; Armelle Riboulleau; Jean Yves Reynaud; Kurt O. Konhauser

doi:10.1038/s41467-019-10620-3

Microbially induced potassium enrichment in Paleoproterozoic shales and implications for reverse weathering on early Earth

Jérémie Aubineau
, Abderrazak El Albani
, Andrey Bekker
, Andrea Somogyi
, Olabode M. Bankole
, Roberto Macchiarelli
, Alain Meunier
, Armelle Riboulleau
, Jean Yves Reynaud
, Kurt O. Konhauser

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

35 Citations (Scopus)

Abstract

Illitisation requires potassium incorporation into a smectite precursor, a process akin to reverse weathering. However, it remains unclear whether microbes facilitate K⁺ uptake to the sediments and whether illitisation was important in the geological past. The 2.1 billion-year-old Francevillian Series of Gabon has been shown to host mat-related structures (MRS) and, in this regard, these rocks offer a unique opportunity to test whether ancient microbes induced illitisation. Here, we show high K content confined to illite particles that are abundant in the facies bearing MRS, but not in the host sandstone and black shale. This observation suggests that microbial biofilms trapped K⁺ from the seawater and released it into the pore-waters during respiration, resulting in illitisation. The K-rich illite developed exclusively in the fossilized MRS thus provides a new biosignature for metasediments derived from K-feldspar-depleted rocks that were abundant crustal components on ancient Earth.

Original language	English
Article number	2670
Journal	Nature Communications
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41467-019-10620-3
Publication status	Published - 1 Dec 2019
Externally published	Yes

ASJC Scopus subject areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/s41467-019-10620-3

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Aubineau, J., El Albani, A., Bekker, A., Somogyi, A., Bankole, O. M., Macchiarelli, R., Meunier, A., Riboulleau, A., Reynaud, J. Y., & Konhauser, K. O. (2019). Microbially induced potassium enrichment in Paleoproterozoic shales and implications for reverse weathering on early Earth. Nature Communications, 10(1), Article 2670. https://doi.org/10.1038/s41467-019-10620-3

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title = "Microbially induced potassium enrichment in Paleoproterozoic shales and implications for reverse weathering on early Earth",

abstract = "Illitisation requires potassium incorporation into a smectite precursor, a process akin to reverse weathering. However, it remains unclear whether microbes facilitate K+ uptake to the sediments and whether illitisation was important in the geological past. The 2.1 billion-year-old Francevillian Series of Gabon has been shown to host mat-related structures (MRS) and, in this regard, these rocks offer a unique opportunity to test whether ancient microbes induced illitisation. Here, we show high K content confined to illite particles that are abundant in the facies bearing MRS, but not in the host sandstone and black shale. This observation suggests that microbial biofilms trapped K+ from the seawater and released it into the pore-waters during respiration, resulting in illitisation. The K-rich illite developed exclusively in the fossilized MRS thus provides a new biosignature for metasediments derived from K-feldspar-depleted rocks that were abundant crustal components on ancient Earth.",

author = "J{\'e}r{\'e}mie Aubineau and \{El Albani\}, Abderrazak and Andrey Bekker and Andrea Somogyi and Bankole, \{Olabode M.\} and Roberto Macchiarelli and Alain Meunier and Armelle Riboulleau and Reynaud, \{Jean Yves\} and Konhauser, \{Kurt O.\}",

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AU - Aubineau, Jérémie

AU - El Albani, Abderrazak

AU - Bekker, Andrey

AU - Somogyi, Andrea

AU - Bankole, Olabode M.

AU - Macchiarelli, Roberto

AU - Meunier, Alain

AU - Riboulleau, Armelle

AU - Reynaud, Jean Yves

AU - Konhauser, Kurt O.

PY - 2019/12/1

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N2 - Illitisation requires potassium incorporation into a smectite precursor, a process akin to reverse weathering. However, it remains unclear whether microbes facilitate K+ uptake to the sediments and whether illitisation was important in the geological past. The 2.1 billion-year-old Francevillian Series of Gabon has been shown to host mat-related structures (MRS) and, in this regard, these rocks offer a unique opportunity to test whether ancient microbes induced illitisation. Here, we show high K content confined to illite particles that are abundant in the facies bearing MRS, but not in the host sandstone and black shale. This observation suggests that microbial biofilms trapped K+ from the seawater and released it into the pore-waters during respiration, resulting in illitisation. The K-rich illite developed exclusively in the fossilized MRS thus provides a new biosignature for metasediments derived from K-feldspar-depleted rocks that were abundant crustal components on ancient Earth.

AB - Illitisation requires potassium incorporation into a smectite precursor, a process akin to reverse weathering. However, it remains unclear whether microbes facilitate K+ uptake to the sediments and whether illitisation was important in the geological past. The 2.1 billion-year-old Francevillian Series of Gabon has been shown to host mat-related structures (MRS) and, in this regard, these rocks offer a unique opportunity to test whether ancient microbes induced illitisation. Here, we show high K content confined to illite particles that are abundant in the facies bearing MRS, but not in the host sandstone and black shale. This observation suggests that microbial biofilms trapped K+ from the seawater and released it into the pore-waters during respiration, resulting in illitisation. The K-rich illite developed exclusively in the fossilized MRS thus provides a new biosignature for metasediments derived from K-feldspar-depleted rocks that were abundant crustal components on ancient Earth.

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Microbially induced potassium enrichment in Paleoproterozoic shales and implications for reverse weathering on early Earth

Abstract

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