Prebiotic atmospheric oxygen levels

It has been argued 1–2 that the early Precambrian atmosphere contained a negligible amount of oxygen and that the transition to the modern oxygen-rich atmosphere began some 2,000 Myr BP when photosynthetic oxygen produced by blue-green algae oxidized ferrous iron in solution and escaped from the oce...

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Bibliographic Details
Published in:Nature (London) 1981-07, Vol.292 (5819), p.136-138
Main Author: Carver, J. H
Format: Article
Language:English
Subjects:
Humanities and Social Sciences
letter
multidisciplinary
Science
Science (multidisciplinary)
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Summary:It has been argued 1–2 that the early Precambrian atmosphere contained a negligible amount of oxygen and that the transition to the modern oxygen-rich atmosphere began some 2,000 Myr BP when photosynthetic oxygen produced by blue-green algae oxidized ferrous iron in solution and escaped from the ocean to the atmosphere. Others 3 have argued for an even earlier occurrence of an oxygen-rich atmosphere. Although photosynthesis has provided the oxygen of the present atmosphere, the photosynthetic model for Precambrian oxygen production has difficulties. There is the problem of identifying the large deposits of reduced carbon needed to account for the red beds 4 and the predominant role of photosynthesis as an oxygen source in the early Precambrian has been questioned on both biochemical and geochemical grounds 5 . Before photosynthesis the only possible abiotic source of atmospheric oxygen would have been the direct photodissociation of water vapour by solar UV photons. What atmospheric oxygen level could have been produced by this purely abiotic process? It has been argued 6 that the abiotic oxygen level was entirely negligible, ≤10 −12 PAL (present atmospheric level), but this assumed that the water vapour content of the palaeoatmosphere was the same as at present with a constant H 2 O mixing ratio of 3.8 p.p.m. above an altitude of 10 km. I argue here that this is too restrictive an assumption and calculate possible atmospheric oxygen levels for larger water vapour mixing ratios which cannot be ruled out by our limited knowledge of Precambrian conditions. Even a moderate oxygen content for the early Precambrian atmosphere could have had significant evolutionary implications because a biologically effective UV ozone screen would be established once the oxygen content exceeded 10 −2 PAL (refs 7–11).
ISSN:0028-0836
1476-4687
DOI:10.1038/292136a0