Abstract

Near-source strong motions of 64 earthquakes (3 ≦ M ≦ 8.1; 10 ≦ R ≦ 54 km) recorded above the Mexican subduction zone are analyzed to study the scaling of peak horizontal acceleration, a max, and Fourier acceleration amplitude spectra, a ( f ), as a function of magnitude M . The a max data reduced to 16 km shows clear dependence on M for M ≦ 6. For M > 6, the existing data suggests that for such events a max does not depend on M . Observation points 16 km above the source are in the far field for earthquakes with M > 6 for the frequencies (>1 Hz) of interest here, so that for such events a ( f ) is easily explained in terms of Brune's source spectra modified by attenuation. The same spectra explain the a max data when Parseval's theorem is used to obtain a rms and the expected a max is computed using random vibration theory (RVT). For larger earthquakes, we modify the point-source model to estimate Fourier amplitude spectra from finite sources, ignoring possible directivity effects. These spectra along with rupture duration T d is used to compute a rms and to estimate a max by applying RVT. The character of the near-source recordings of 6 ≦ M ≦ 8.1 earthquakes in Mexico suggests that the assumption of stationarity over T d is reasonable. The results from the model show that beyond M ≅ 6, the dependence of a max on M decreases; for M > 7.5 a max becomes essentially independent of M . The a max and a ( f ) observed for M ≦ 6.5 may be interpreted in terms of this finite-source model with stress drops Δσ of 40 to 100 bars and an appropriate site attenuation parameter. From a possible M = 7.5 to 8 earthquake in the Guerrero gap the expected a max from the finite-source model in Acapulco, corresponding to Δσ = 100 bars and κ = 0.023s, is roughly 1 2 g.