Questioning the evidence for Earth's oldest fossils

Brasier, Martin D.; Green, Owen R.; Jephcoat, Andrew P.; Kleppe, Annette K.; Van Kranendonk, Martin J.; Lindsay, John F.; Steele, Andrew; Grassineau, Nathalie V.

Questioning the evidence for Earth's oldest fossils

Martin D. Brasier (), Owen R. Green, Andrew P. Jephcoat, Annette K. Kleppe, Martin J. Van Kranendonk, John F. Lindsay, Andrew Steele and Nathalie V. Grassineau
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Martin D. Brasier: University of Oxford
Owen R. Green: University of Oxford
Andrew P. Jephcoat: University of Oxford
Annette K. Kleppe: University of Oxford
Martin J. Van Kranendonk: Geological Survey of Western Australia
John F. Lindsay: Research School of Earth Sciences, Australian National University
Andrew Steele: School of Earth, Environmental and Physical Sciences, University of Portsmouth
Nathalie V. Grassineau: Royal Holloway University of London

Nature, 2002, vol. 416, issue 6876, 76-81

Abstract: Abstract Structures resembling remarkably preserved bacterial and cyanobacterial microfossils from ∼3,465-million-year-old Apex cherts of the Warrawoona Group in Western Australia1,2,3,4 currently provide the oldest morphological evidence for life on Earth and have been taken to support an early beginning for oxygen-producing photosynthesis5. Eleven species of filamentous prokaryote, distinguished by shape and geometry, have been put forward as meeting the criteria required of authentic Archaean microfossils1,2,3,4,5, and contrast with other microfossils dismissed as either unreliable or unreproducible1,3,6,7. These structures are nearly a billion years older than putative cyanobacterial biomarkers8, genomic arguments for cyanobacteria9, an oxygenic atmosphere10 and any comparably diverse suite of microfossils5. Here we report new research on the type and re-collected material, involving mapping, optical and electron microscopy, digital image analysis, micro-Raman spectroscopy and other geochemical techniques. We reinterpret the purported microfossil-like structure as secondary artefacts formed from amorphous graphite within multiple generations of metalliferous hydrothermal vein chert and volcanic glass. Although there is no support for primary biological morphology, a Fischer–Tropsch-type synthesis of carbon compounds and carbon isotopic fractionation is inferred for one of the oldest known hydrothermal systems on Earth.

Date: 2002
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DOI: 10.1038/416076a

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