ALBERT

Notes: We use simulations of 1-D, 2-D and 3-D wave propagation to identify the major causes of low-frequency (0.2–1.2 Hz) seismic amplification in the Salt Lake Basin. For a simple two-layer basin model and a vertically incident P wave, we examine how amplification is influenced by mode conversion, surface-wave generation, impedance effects at the sediment-bedrock boundary, resonance, and 2-D and 3-D focusing and scattering. Results show the following.(1) Approximately 30 per cent of the total cumulative kinetic energy at the Salt Lake Valley floor consists of shear-wave energy generated by P-to-S converted waves and surface waves. The surface waves appear to be generated primarily along the edges of the basin, and the instantaneous S/P energy ratio in the sedimentary layer is as large as 3.(2) The largest peak particle velocity at the free surface is due to the direct P wave. The value is roughly predicted by the transmission coefficient of 1.46 at the sediment-bedrock interface, i.e. a normally incident P wave in the stiff bedrock will be magnified in amplitude by 1.46 times as it enters the softer sediments.(3) The low-frequency elastic response of the two-layer Salt Lake Basin model is characterized by surface-wave propagation and resonance from vertically interfering waves.(4) The peak particle velocities, cumulative kinetic energies, and mean spectral magnitudes computed from the 2-D (1-D) synthetics underestimate the values computed from the 3-D synthetics by up to 40 per cent (48 per cent) along a profile above the deepest part of the basin model. The 2-D and 1-D signal duration times underestimate the 3-D values by up to 59 and 94 per cent, respectively. Our results suggest that 2-D basin modelling may yield good approximations to the 3-D ground motion amplification above the deepest part of the Salt Lake Basin.Our results show that several mechanisms contribute significantly to low-frequency seismic amplification in the semi-consolidated sediments of the Salt Lake Basin—P-to-S wave conversion, surface-wave generation, impedance effects at the sediment-bedrock boundary, and resonance. Future attempts to estimate ground motion amplification in the Salt Lake Basin should therefore account for the amplification effects of all these mechanisms.