Title of article
Overview of continuum and particle dynamics methods for mechanical modeling of contractional geologic structures
Author/Authors
Gray، نويسنده , , Gary G. and Morgan، نويسنده , , Julia K. and Sanz، نويسنده , , Pablo F.، نويسنده ,
Issue Information
ماهنامه با شماره پیاپی سال 2014
Pages
18
From page
19
To page
36
Abstract
Mechanically-based numerical modeling is a powerful tool for investigating fundamental processes associated with the formation and evolution of both large and small-scale geologic structures. Such methods are complementary with traditional geometrically-based cross-section analysis tools, as they enable mechanical validation of geometric interpretations. A variety of numerical methods are now widely used, and readily accessible to both expert and novice. We provide an overview of the two main classes of methods used for geologic studies: continuum methods (finite element, finite difference, boundary element), which divide the model into elements to calculate a system of equations to solve for both stress and strain behavior; and particle dynamics methods, which rely on the interactions between discrete particles to define the aggregate behavior of the system. The complex constitutive behaviors, large displacements, and prevalence of discontinuities in geologic systems, pose unique challenges for the modeler. The two classes of methods address these issues differently; e.g., continuum methods allow the user to input prescribed constitutive laws for the modeled materials, whereas the constitutive behavior ‘emerges’ from particle dynamics methods. Sample rheologies, case studies and comparative models are presented to demonstrate the methodologies and opportunities for future modelers.
Keywords
discrete element , Boundary element , Finite difference , Contractional structures , constitutive laws , Particle Dynamics , plasticity , Structural modeling , Finite element
Journal title
Journal of Structural Geology
Serial Year
2014
Journal title
Journal of Structural Geology
Record number
2228105
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