Seismic earth pressures on cantilever retaining structures

An experimental and analytical program was designed and conducted to evaluate the magnitude and distribution of seismically induced lateral earth pressures on cantilever retaining structures with dry medium dense sand backfill. Results from two sets of dynamic centrifuge experiments and two-dimensional nonlinear finite-element analyses show that maximum dynamic earth pressures monotonically increase with depth and can be reasonably approximated by a triangular distribution. Moreover, dynamic earth pressures and inertia forces do not act simultaneously on the cantilever retaining walls. As a result, designing cantilever retaining walls for maximum dynamic earth pressure increment and maximum wall inertia, as is the current practice, is overly conservative and does not reflect the true seismic response of the wall-backfill system. The relationship between the seismic earth pressure increment coefficient ([DELTA][K.sub.AE]) at the time of maximum overall wall moment and peak ground acceleration obtained from our experiments suggests that seismic earth pressures on cantilever retaining walls can be neglected at accelerations below 0.4 g. This finding is consistent with the observed good seismic performance of conventionally designed cantilever retaining structures. DOI: 10.1061/(ASCE)GT.1943-5606.0000351 CE Database subject headings: Retaining walls; Earth pressure; Seismic effects; Earthquakes; Centrifuge models; Numerical models; Simulation; Seismic design; Backfills. Author keywords: Retaining walls; Earth pressures; Earthquakes; Centrifuge models; Numerical models; Simulation; Seismic design; Backfills.