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Basalt vesicularity as a measure of atmospheric pressure and palaeoelevation

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Abstract

THE pressure in, and thus the size of, a bubble in a lava flow is determined by the atmospheric pressure and the hydrostatic pressure of the overlying lava. If atmospheric sea-level pressure is known (or assumed), vesicle size distributions in basalt flows can thus be used as an indicator of the palaeoelevation of emplacement1. Here we show by analysis of the vesicle size distribution of basalt samples collected from the summit and base of Mauna Loa volcano in Hawaii that the technique provides estimates of ambient pressure that are accurate to within 0.1 bar, and thus estimates of elevation with a resolution of about 1,400m. This palaeoaltimetric technique should find useful application in palaeogeographical reconstruction2 for times when sea-level pressure was similar to the present value. (Conversely, if the elevation of emplacement is known, our technique should be able to provide a measure of sea-level palaeopressure.) Unlike palaeo-botanical methods for estimating elevations3–6, this method does not have to assume a relationship between temperature and altitude; on the other hand, its use is restricted to lava flows that have had a simple emplacement history.

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Authors and Affiliations

  1. Institute for the Study of Earth, Oceans and Space, University of New Hampshire, Durham, New Hampshire, 03824, USA

    Dork L. Sahagian

  2. Department of Geological Sciences, The Ohio State University, Columbus, Ohio, 43210, USA

    Joseph E. Maus

Authors
  1. Dork L. Sahagian
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  2. Joseph E. Maus
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Sahagian, D., Maus, J. Basalt vesicularity as a measure of atmospheric pressure and palaeoelevation. Nature 372, 449–451 (1994). https://doi.org/10.1038/372449a0

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