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The influence of natural mineral coatings on feldspar weathering

Nature volume 395pages 588–591 (1998)Cite this article

Abstract

Quantification of the rate of weathering of feldspar, the most abundant mineral in the Earth's crust, is required to estimate accurately carbon dioxide fluxes over geological timescales and to model groundwater chemistry. Laboratory dissolution rates, however, are consistently found to be up to four orders of magnitude higher than the ‘natural' rates1,2 measured in the field. Although this discrepancy has been attributed to several factors2, previous research has tended to suggest that the underlying mechanism of feldspar dissolution under acidic pH may differ between the field and the laboratory3. Here we demonstrate that weathered albite surfaces, like laboratory-dissolved samples, are sodium- and aluminium-depleted, indicating that the dissolution mechanism in acidic soils is similar to that in acidic laboratory solutions. We find that microtopography images are consistent with dissolution occurring at specific surface sites — indicative of surface-controlled dissolution dominated by a non-stoichiometric layer. Elevated aluminium and silicon ratios reported previously3,4, and used to suggest a mechanism for field weathering different from laboratory dissolution3, can alternatively be explained by a thin, hydrous, patchy, natural coating of amorphous and crystalline aluminosilicate. This coating, which is largely undetected under scanning electron microscopy after cleaning, but visible under atomic force microscopy, alters surface chemistry measurements and may partially inhibit the field dissolution rate.

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Figure 1: Tapping Mode instrument AFM amplitude image (2.5 × 2.5 μm) in a coating-free area of peristeritic albite weathered for 3 years.
Figure 2: SIMS signal ratios as a function of depth into the albite surface.
Figure 3: Al/Si (empty circles) and Na/Si (empty triangles) atomic ratios for albite versus time of weathering, as measured by XPS.

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Acknowledgements

We thank V. Bojan, D. Voigt, S. Yau, E. Rufe and B. Turner for discussions, M. Lee for feldspar TEM analyses, J. Hamilton for XPS analyses and Y. Chen and C. Doud for assistance with burial experiments. This work was funded by a grant from the Office of Basic Energy Sciences, Dept of Energy.

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Author notes

  1. M. A. Nugent

    Present address: Department of Geosciences, SUNY at Stony Brook, Stony Brook, New York, 11794-2100, USA

Authors and Affiliations

  1. Department of Geosciences,

    M. A. Nugent & S. L. Brantley

  2. Department of Material Science and Engineering, The Pennsylvania State University, University Park, 16802, Pennsylvania, USA

    C. G. Pantano

  3. Department of Geology, Kent State University, Kent, 44242, Ohio, USA

    P. A. Maurice

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  1. M. A. Nugent
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  2. S. L. Brantley
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Correspondence to M. A. Nugent.

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Nugent, M., Brantley, S., Pantano, C. et al. The influence of natural mineral coatings on feldspar weathering. Nature 395, 588–591 (1998). https://doi.org/10.1038/26951

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