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A Comparative Analysis of the Microfabrics of Surface Horizons and Desert Varnish in Extremely Arid Soils of the Mojave (USA) and Trans-Altai Gobi (Mongolia) Deserts

  • Genesis and Geography of Soils
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Abstract

The mineralogical composition of coarse fraction and characteristic features of the micro- and submicrofabrics and chemical composition of desert varnish on gravels of desert pavements and the underlying vesicular crust soil horizons were studied in the extremely arid soils of the Mojave (USA) and Trans-Altai Gobi (Mongolia) deserts. A set of common diagnostic features of elementary pedogenetic processes was identified in the automorphic desert soils developed on ancient (70–90 ka) piedmont plains composed of alluvial deposits with the high content of red-earth clay. The results of this study attest to the long and complicated history of the extremely arid soils with alternation of the humid and arid phases of pedogenesis reflected in a specific combination of textural (clay-illuvial) and carbonate pedofeatures and in the distribution patterns of iron, manganese, titanium, and barium in different layers of the desert varnish. The chemical composition of the latter did not depend on the mineralogical composition of the underlying substrates and was formed with active participation of soil microorganisms. This allowed us to conclude about the polygenetic (accretionary–microbiological) nature of desert varnish.

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Authors and Affiliations

  1. Dokuchaev Soil Science Institute, per. Pyzhevskii 7, Moscow, 119017, Russia

    M. P. Lebedeva & V. A. Shishkov

  2. Institute of Geography, Russian Academy of Sciences, per. Staromonetnyi 29, Moscow, 119017, Russia

    M. P. Lebedeva

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  1. M. P. Lebedeva
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  2. V. A. Shishkov
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Correspondence to M. P. Lebedeva.

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Original Russian Text © M.P. Lebedeva, V.A. Shishkov, 2016, published in Pochvovedenie, 2016, No. 2, pp. 182–199.

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Lebedeva, M.P., Shishkov, V.A. A Comparative Analysis of the Microfabrics of Surface Horizons and Desert Varnish in Extremely Arid Soils of the Mojave (USA) and Trans-Altai Gobi (Mongolia) Deserts. Eurasian Soil Sc. 49, 163–179 (2016). https://doi.org/10.1134/S106422931512011X

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