• Title of article

    Fractal models for predicting soil hydraulic properties: a review

  • Author/Authors

    Giménez، نويسنده , , D. and Perfect، نويسنده , , E. and Rawls، نويسنده , , W.J. and Pachepsky، نويسنده , , Ya.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 1997
  • Pages
    23
  • From page
    161
  • To page
    183
  • Abstract
    Modern hydrological models require information on hydraulic conductivity and soil-water retention characteristics. The high cost and large spatial variability of measurements makes the prediction of these properties a viable alternative. Fractal models describe hierarchical systems and are suitable to model soil structure and soil hydraulic properties. Deterministic fractals are often used to model porous media in which scaling of mass, pore space, pore surface and the size-distribution of fragments are all characterized by a single fractal dimension. Experimental evidence shows fractal scaling of these properties between upper and lower limits of scale, but typically there is no coincidence in the values of the fractal dimensions characterizing different properties. This poses a problem in the evaluation of the contrasting approaches used to model soil-water retention and hydraulic conductivity. Fractal models of the soil-water retention curve that use a single fractal dimension often deviate from measurements at saturation and at dryness. More accurate models should consider scaling domains each characterized by a fractal dimension with different morphological interpretations. Models of unsaturated hydraulic conductivity incorporate fractal dimensions characterizing scaling of different properties including parameters representing connectivity. Further research is needed to clarify the morphological properties influencing the different scaling domains in the soil-water retention curve and unsaturated hydraulic conductivity. Methods to functionally characterize a porous medium using fractal approaches are likely to improve the predictability of soil hydraulic properties.
  • Keywords
    fragmentation , Pore volume , Pore surface roughness , Hydraulic conductivity , Water retention
  • Journal title
    Engineering Geology
  • Serial Year
    1997
  • Journal title
    Engineering Geology
  • Record number

    2344660