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The origin of non-sea-salt sulphate in the Mount Logan ice core

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Abstract

IT has been suggested1 that oxidized sulphur compounds might play an important part in influencing climate, as they serve as cloud condensation nuclei and thus could affect the radiative properties of clouds. Schwartz2, however, finds no evidence for a climate response arising from the increased concentrations of oxidized sulphur compounds resulting from the burning of fossil fuels. He contends that such a response should be detectable if these compounds are indeed important, as they are distributed widely in the atmosphere. Measurements of sulphate concentrations3,4 in an ice core from Mount Logan (5,951 m), in northwestern Canada, indicate that the background concentration of non-sea-salt sulphate in snow deposited on the ice cap during the past century has remained nearly constant. Here we report 210Pb/137Cs ratios measured in the ice core and in soil cores collected at nearby low-altitude sites. As the 210Pb/137Cs ratio in sub-micrometre aerosols decreases with altitude, and as the non-sea-salt sulphate to210Pb concentration ratios in snow deposited on Mount Logan are lower than values reported5 for aerosol samples collected at nearby high-latitude, low-altitude sites, our data indicate that the ice core contains sub-micrometre aerosols scavenged from the middle or upper troposphere, or both. Thus, the apparent lack of a secular increase in the non-sea-salt sulphate concentrations at Mount Logan suggests that anthropogenic oxidized sulphur compounds probably have not significantly affected a large part of the middle or upper troposphere (or both) in the remote Northern Hemisphere.

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Authors and Affiliations

  1. Department of Geophysical Sciences, University of Chicago, Chicago, Illinois, 60637, USA

    M. C. Monaghan

  2. National Hydrology Research Institute, Environment Canada, Saskatoon, Saskatchewan, Canada, S7N 3H5

    G. Holdsworth

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  1. M. C. Monaghan
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  2. G. Holdsworth
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Monaghan, M., Holdsworth, G. The origin of non-sea-salt sulphate in the Mount Logan ice core. Nature 343, 245–248 (1990). https://doi.org/10.1038/343245a0

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