Group B, Poster #120, Computational Science (CS)
Numerical modeling of ground surface deformation related to thrust and reverse fault earthquakes: A discrete element approach
Poster Image:
Poster Presentation
2022 SCEC Annual Meeting, Poster #120, SCEC Contribution #12536 VIEW PDF
arameters, such as fault geometry and sediment/soil properties, control ground deformation patterns including scarp dip, width, and patterns of secondary folding and fracturing. The DEM method is well suited to this investigation as it can effectively model the geologic processes of faulting at depth, as well as the granular mechanics of soil and sediment deformation in the shallow subsurface. We discuss a suite of models that illustrate characteristic patterns of ground surface deformation and show how these vary as a function of the accumulation of slip on a fault, the fault dip angle, and sediment/soil properties such as density of grain packing and the cohesion and tensile strength of particle bonds. Our initial results show that localized fault scarps are most prominent in cases with stiff sediments and steeply dipping faults (40º to 60º), whereas broader deformation is more prominent with soft sediments and shallowly dipping faults (less than 30º). Fault scarp widths range from 2.0 m to 20 m with wider deformation zones defined by secondary fractures and backthrusts. Furthermore, we show how our DEM models can be designed to evaluate the impact of additional earthquakes occurring between periods of sediment deposition to represent and help interpret patterns commonly found in paleoseismic trenches. Collectively, these results help guide both deterministic and probabilistic assessment of fault rupture hazards.
SHOW MORE
SHOW MORE