Synthetic Pn and Sn phases and the frequency dependence of Q of oceanic lithosphere

Abstract

The oceanic lithosphere is an extremely efficient waveguide for high‐frequency seismic energy. In particular, the propagation of the regional to teleseismic oceanic P_n and S_n phases is largely controlled by properties of the oceanic plates. The shallow velocity gradient in the sub‐Moho lithosphere results in a nearly linear travel time curve for these oceanic phases and an onset velocity near the material velocity of the uppermost mantle. The confinement of P_n/S_n to the lithosphere imposes a constraint on the maximum range that a normally refracted wave can be observed. The rapid disappearance of S_n and the discontinuous drop in P_n/S_n group velocity beyond a critical distance, dependent upon the local thickness of the lithosphere, are interpreted as a shadowing effect of the low Q asthenosphere. Wave number integration was used to compute complete synthetic seismograms for a model of oceanic lithosphere. The results were compared to data collected during the 1983 Ngendei Seismic Experiment in the southwest Pacific. The P_n/S_n coda is successfully modeled as a sum of leaky organ‐pipe modes in the sediment layer and oceanic water column. While scattering is present to some degree, it is not required to explain the long duration and complicated nature of the P_n/S_n wave trains. The presence of extremely high frequencies in P_n/S_n phases and the greater efficiency of S_n than P_n propagation are interpreted in terms of an absorption band rheology. A shorter high‐frequency relaxation time for P waves than for S waves results in a rheology with the property that Q_α > Q_β at low frequency while Q_β > Q_α at high frequency, consistent with the teleseismic P_n/S_n observations. The absorption band model is to viewed as only an approximation to the true frequency dependence of Q in the oceanic lithosphere for which analytic expressions for the material dispersion have been developed.