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The exaerobic zone, a new oxygen-deficient marine biofacies

Nature volume 327pages 54–56 (1987)Cite this article

Abstract

Classical biofacies models1,2 for reconstructing palaeoenvironments of strata deposited in oxygen-deficient marine settings define three principal facies: aerobic (> 1.0 ml 1−1 O2), dysaerobic (1.0 to 0.1 ml 1−1 O2) and anaerobic (<0.1 ml 1−1 O2) zones. These models have postulated a decrease in organism size and degree of calcification as well as a drastic reduction in the relative percentage of fauna possessing calcified skeletons as the dysaerobic/anaerobic boundary is approached. Through use of evidence independent of that provided by body fossils, we demonstrate here that in portions of the Monterey Formation (Miocene; California) the bivalve Anadara montereyana occurs in situ almost exclusively in strata deposited at the dysaerobic/anaerobic boundary. The occurrence of fossils of large well-calcified benthic macroinvertebrates at this redox boundary contradicts classical biofacies models1,2 and there-fore provides the basis for definition of a new oxygen-related biofacies, the 'exaerobic zone’. The exaerobic zone concept, when adjusted for differences in basin configuration and palaeoceano-graphic conditions, provides a potentially useful model for explain-ing occurrences of shelly benthic fossils within laminated, organic-rich strata of other Phanerozoic marine sequences.

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Authors and Affiliations

  1. Department of Geology, Auburn University, Auburn, Alabama, 36830, USA

    Charles E. Savrda

  2. Department of Geological Sciences, University of Southern California, Los Angeles, California, 90089-0741, USA

    David J. Bottjer

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  1. Charles E. Savrda
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Savrda, C., Bottjer, D. The exaerobic zone, a new oxygen-deficient marine biofacies. Nature 327, 54–56 (1987). https://doi.org/10.1038/327054a0

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