Evaluating sensitivity of silicate mineral dissolution rates to physical weathering using a soil evolution model (SoilGen2.25)
Author:
Opolot E., Finke P. A.ORCID
Abstract
Abstract. Silicate mineral dissolution rates depend on the interaction of a number of factors categorized either as intrinsic (e.g. mineral surface area, mineral composition) or extrinsic (e.g. climate, hydrology, biological factors, physical weathering). Estimating the integrated effect of these factors on the silicate mineral dissolution rates therefore necessitates the use of fully mechanistic soil evolution models. This study applies a mechanistic soil evolution model (SoilGen) to explore the sensitivity of silicate mineral dissolution rates to the integrated effect of other soil forming processes and factors. The SoilGen soil evolution model is a 1-D model developed to simulate the time-depth evolution of soil properties as a function of various soil forming processes (e.g. water, heat and solute transport, chemical and physical weathering, clay migration, nutrient cycling and bioturbation) driven by soil forming factors (i.e., climate, organisms, relief, parent material). Results from this study show that although soil solution chemistry (pH) plays a dominant role in determining the silicate mineral dissolution rates, all processes that directly or indirectly influence the soil solution composition equally play an important role in driving silicate mineral dissolution rates. Model results demonstrated a decrease of silicate mineral dissolution rates with time, an obvious effect of texture and an indirect but substantial effect of physical weathering on silicate mineral dissolution rates. Results further indicated that clay migration and plant nutrient recycling processes influence the pH and thus the silicate mineral dissolution rates. Our silicate mineral dissolution rates results fall between field and laboratory rates but were rather high and more close to the laboratory rates owing to the assumption of far from equilibrium reaction used in our dissolution rate mechanism. There is therefore need to include secondary mineral precipitation mechanism in our formulation. In addition, there is need for a more detailed study that is specific to field sites with detailed measurements of silicate mineral dissolution rates, climate, hydrology and mineralogy to enable the calibration and validation of the model. Nevertheless, this study is another important step to demonstrate the critical need to couple different soil forming processes with chemical weathering in order to explain differences observed between laboratory and field measured silicate mineral dissolution rates.
Publisher
Copernicus GmbH
Reference68 articles.
1. Anderson, S. P., von Blanckenburg, F., and White, a. F.: Physical and Chemical Controls on the Critical Zone, Elements, 3, 315–319, 2007. 2. Beaulieu, E., Goddéris, Y., Labat, D., Roelandt, C., Calmels, D., and Gaillardet, J.: Modeling of water-rock interaction in the Mackenzie basin: Competition between sulfuric and carbonic acids, Chem. Geol., 289, 114–123, 2011. 3. Blum A. E. and Stillings L. L. Feldspar dissolution kinetics, in: Chemical Weathering Rates of Silicate Minerals, edited by: White, A. F. and Brantley, S. L., Mineral. Soc. Am., 31, 291–351, 1995. 4. Brady, P. V. and Walther, J. V.: Kinetics of quartz dissolution at low temperatures, Chem. Geol., 82, 253–264, 1990. 5. Brady, P. V., Dorn, R. I., Brazel, A. J., Clark, J., Moore, R. B., and Glidewell, T.: Direct measurement of the combined effects of lichen, rainfall, and temperature onsilicate weathering, Geochim. Cosmochim. Acta, 63, 3293–3300, 1999.
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