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Soils Branch, Alberta Environmental Centre, Bag 4000, Vegreville, Alberta, Canada, T9C 1T4
Dep. of Crop and Soil Science, Oregon State Univ., Corvallis, OR 97331
*Corresponding author (dhmcnabb{at}aec.env.gov.ab.ca).
ABSTRACT
Development of a comprehensive model for soil deformation remains an important research goal for soil scientists. Accounting for the effect of changing soil water content is a critical component of this goal. A nonlinear mathematical model for prediction of the bulk density as a function of soil water content and normal stress was developed and tested. The proposed model is an extension of a previously developed nonlinear model for soil compression obtained by including dgree of soil saturation as the measurer of soil water content. The model predicts bulk density at both low and high stresses and at soil water contents ranging from the permanent wilting point to saturation. The model was tested with data obtained from one-dimensional consolidation tests of undisturbed soil cores from the 7- to 12-cm depth of three Andisols characterized by amorphous clay minerals or volcanic ash and one fine-textured mineral soil containing a mixture of crystalline clay-sized minerals. The standard error of the regression of predicted vs. measured compressed bulk densities ranged from 0.029 to 0.040 Mg m-3. Application of the model showed that the soil compressibility varied substantially between soils. The compressibility of Andisols was less sensitive to differences in soil water content than was the fine-textured soil that contained few amorphous clay minerals. the proposed model is a promising new method for predicting the compressibility of soils for a wide range of stresses and soil water contenst.
This is Paper 3123 of the Forest Research Lab., Oregon State Univ., Corvallis. This study was funded by the Forestry Intensified Research (FIR) Program in cooperation with the USDI Bureau of Land Management, USDA Forest Service, southwest Oregon counties and forest industries, and the Forest Research Lab., Oregon State Univ.
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