• Title of article

    Comparisons between analogue and numerical models of thrust wedge development

  • Author/Authors

    Ellis، نويسنده , , S. and Schreurs، نويسنده , , G. and Panien، نويسنده , , Marion، نويسنده ,

  • Issue Information
    ماهنامه با شماره پیاپی سال 2004
  • Pages
    17
  • From page
    1659
  • To page
    1675
  • Abstract
    Analogue and finite element numerical models with frictional and viscous properties are used to model thrust wedge development. Comparison between model types yields valuable information about analogue model evolution, scaling laws and the relative strengths and limitations of the techniques. Both model types show a marked contrast in structural style between ‘frictional-viscous domains’ underlain by a thin viscous layer and purely ‘frictional domains’. Closely spaced thrusts form a narrow and highly asymmetric fold-and-thrust belt in the frictional domain, characterized by in-sequence propagation of forward thrusts. In contrast, the frictional-viscous domain shows a wide and low taper wedge and a thrust belt with a more symmetrical vergence, with both forward and back thrusts. The frictional-viscous domain numerical models show that the viscous layer initially simple shears as deformation propagates along it, while localized deformation resulting in the formation of a pop-up structure occurs in the overlying frictional layers. In both domains, thrust shear zones in the numerical model are generally steeper than the equivalent faults in the analogue model, because the finite element code uses a non-associated plasticity flow law. Nevertheless, the qualitative agreement between analogue and numerical models is encouraging. It shows that the continuum approximation used in numerical models can be used to model frictional materials, such as sand, provided caution is taken to properly scale the experiments, and some of the limitations are taken into account.
  • Keywords
    Analogue modelling , Numerical modelling , thrust wedges , strain-softening , sand , Detachment , Scaling , Frictional , viscous
  • Journal title
    Journal of Structural Geology
  • Serial Year
    2004
  • Journal title
    Journal of Structural Geology
  • Record number

    2225571