Abstract. Archaean hydrothermal chert veins commonly contain abundant organic carbon of
uncertain origin (abiotic vs. biotic). In this study, we analysed kerogen
contained in a hydrothermal chert vein from the ca. 3.5 Ga Dresser
Formation (Pilbara Craton, Western Australia). Catalytic hydropyrolysis
(HyPy) of this kerogen yielded n-alkanes up to n-C22, with a sharp
decrease in abundance beyond n-C18. This distribution
(≤ n-C18) is very similar to that observed in HyPy products of
recent bacterial biomass, which was used as reference material, whereas it
differs markedly from the unimodal distribution of abiotic compounds
experimentally formed via Fischer–Tropsch-type synthesis. We therefore
propose that the organic matter in the Archaean chert veins has a primarily
microbial origin. The microbially derived organic matter accumulated in
anoxic aquatic (surface and/or subsurface) environments and was then
assimilated, redistributed and sequestered by the hydrothermal fluids
(“hydrothermal pump hypothesis”).
Paleoarchean rocks from the Pilbara Craton of Western Australia provide a variety of clues to the existence of early life on Earth, such as stromatolites, putative microfossils and geochemical signatures of microbial activity. However, some of these features have also been explained by non-biological processes. Further lines of evidence are therefore required to convincingly argue for the presence of microbial life. Here we describe a new type of microbial mat facies from the 3.4 Ga Strelley Pool Formation, which directly overlies well known stromatolitic carbonates from the same formation. This microbial mat facies consists of laminated, very fine-grained black cherts with discontinuous white quartz layers and lenses, and contains small domical stromatolites and wind-blown crescentic ripples. Light- and cathodoluminescence microscopy, Raman spectroscopy, and time of flight—secondary ion mass spectrometry (ToF-SIMS) reveal a spatial association of carbonates, organic material, and highly abundant framboidal pyrite within the black cherts. Nano secondary ion mass spectrometry (NanoSIMS) confirmed the presence of distinct spheroidal carbonate bodies up to several tens of μm that are surrounded by organic material and pyrite. These aggregates are interpreted as biogenic. Comparison with Phanerozoic analogues indicates that the facies represents microbial mats formed in a shallow marine environment. Carbonate precipitation and silicification by hydrothermal fluids occurred during sedimentation and earliest diagenesis. The deciphered environment, as well as the δ13C signature of bulk organic matter (-35.3‰), are in accord with the presence of photoautotrophs. At the same time, highly abundant framboidal pyrite exhibits a sulfur isotopic signature (δ34S = +3.05‰; Δ33S = 0.268‰; and Δ36S = -0.282‰) that is consistent with microbial sulfate reduction. Taken together, our results strongly support a microbial mat origin of the black chert facies, thus providing another line of evidence for life in the 3.4 Ga Strelley Pool Formation.
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