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Published Online: 4 September 2023

Stromatolite-like Structures Within Microbially Laminated Sandstones of the Paleoarchean Moodies Group, Barberton Greenstone Belt, South Africa

Publication: Astrobiology
Volume 23, Issue Number 9

Abstract

We report abundant small calcareous mounds associated with fossilized kerogenous microbial mats in tidal-facies sandstones of the predominantly siliciclastic Moodies Group (ca. 3.22 Ga) of the Barberton Greenstone Belt (BGB), South Africa and Eswatini. Most of the bulbous, internally microlaminated mounds are several centimeters in diameter and formed at the sediment-water interface contemporaneously with sedimentation. They originally consisted of Fe-Mg-Mn carbonate, which is now largely silicified; subtle internal compositional laminations are composed of organic matter and sericite. Their presence for >6 km along strike, their restriction to the inferred photic zone, and the internal structure suggest that mineral precipitation was induced by photosynthetic microorganisms. Similar calcareous mounds in this unit also occur within and on top of fluid-escape conduits, suggesting that carbonate precipitation may either have occurred abiogenically or involved chemotrophic metabolism(s) utilizing the oxidation of organic matter, methane, or hydrogen, the latter possibly generated by serpentinization of underlying ultramafic rocks. Alternatively or additionally, carbonate may have precipitated abiotically where heated subsurface fluids, sourced by the intrusion of a major Moodies-age sill, reached the tidal flats. In summary, precipitation mechanisms may have been variable; the calcareous mounds may represent “hybrid carbonates” that may have originated from the small-scale overlap of bioinduced and abiotic processes in space and time. Significantly, the widespread occurrence of these stromatolite-like structures in a fully siliciclastic, high-energy tidal setting broadens search criteria in the search for life on Mars while their possible hybrid origin challenges our ability to unambiguously identify a biogenic component.

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cover image Astrobiology
Astrobiology
Volume 23Issue Number 9September 2023
Pages: 926 - 935
PubMed: 37527187

History

Published online: 4 September 2023
Published in print: September 2023
Published ahead of print: 1 August 2023
Accepted: 24 May 2023
Received: 31 January 2023

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Department of Geosciences, Friedrich-Schiller-University Jena, Germany.
S. Reimann
Department of Geosciences, Friedrich-Schiller-University Jena, Germany.
M. Homann
University College London, London, UK.

Notes

Address correspondence to: C. Heubeck, Dept of Geosciences, Friedrich-Schiller-Universitat Jena, Burgweg 11, Jena 07749, Germany [email protected]

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