Pn for the Nevada Test Site

Burdick, L. J.; Saikia, Chandan K.; Smith, N. F.

doi:10.1029/gm065p0197

Cited by 1 publication

(2 citation statements)

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“…Low-velocity zones, on the other hand, will not have a strong effect on the trapped Pnt energy. In the preceding we have discussed the possibility of developing an automated discriminant based on the wave-form information in Pnt similar to the P n waveform discriminant developed by Burdick et al [1988]. Such a procedure would require development of a standard P g waveform for explosions which could be compared with waveforms of events of unknown origin.…”

Section: Discussionmentioning

confidence: 99%

“…Several approaches could be attempted for developing such standard waveforms. The most straightforward would be simply to form empirical averages as Burdick et al [1988] did for Pn' A drawback to this approach is that it might require calibration in each new area. A second approach would be to develop synthetics based on knowledge of local crust and upper mantle structure.…”

Section: Discussionmentioning

confidence: 99%

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Fine structure of P_nl waves from explosions

Saikia¹,

Burdick²

1991

J. Geophys. Res.

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The long‐period character of P nl waves from many tectonic regimes has been modeled in the past using a simple homogeneous layer over a half‐space crust model. Scant attention has been paid to the short‐period wave form character. In this study the P nl waves from Nevada Test Site explosions as recorded on a regional digital seismic array have been modeled in the period range 1–10 s. The fine structure of the P nl waveform has been carefully analyzed. The effects of a realistic velocity gradient at the free surface or a velocity transition zone at the crust‐mantle boundary have been calculated. A free surface gradient of even a moderate nature has a major effect on the waveforms, whereas a finite crust‐mantle transition apparently does not. We have developed an efficient scheme to implement the wavenumber integration theory for computing short‐period P nl waves at regional distances. We utilized both the wavenumber integration and a generalized ray theory synthetic seismogram code for use in our analysis. The former was used to compute exact, though band‐limited, synthetics. The latter was used to determine which generalized ray paths contributed the primary energy to the major features of the waveforms. For the simple one‐layer crust model the dominant energy to the critically reflected P wave portion of the wave comes from the primary ray reflected from the mantle. We refer to this as.PmP similar to the notation of PcP for the primary core reflection. The next high‐amplitude energy is associated with a group of ray paths with at least one converted mode (i.e., P converting to S and vice versa). If the wave velocities are gradientlike within the top few kilometers of the model (6 km in this study), the contribution from 2PmP (a ray reflecting twice from the crust‐mantle interface) ray path becomes significant. The converted group of rays still contributes but not strongly. Free surface reflections become significant with the surface gradient present, whereas they are not important for the simple one‐layer model. Besides the direct Pn, four major ray groups have been specifically identified in the observed waveforms and shown to dominate the wave shape. These are the PmP and 2Pmp groups, the converted group, and the 2Pn head wave group. The 2PmP and 2Pn groups are portions of the same generalized rays. Since the converted group of rays loses significance in the presence of a realistic free surface gradient, the onset of the critically reflected portion of the Pnl waveform can be modeled as primarily an interaction between PmP and 2Pmp. The increased importance of depth phases in this part of the waves implies that it may be useful in improving source discrimination capabilities. Low‐Q surface layers have been explored as a possible physical mechanism for the resolving power of regional spectral discriminants. Such a mechanism appears plausible. If this is the dominant mechanism in differentiating earthquake and explosion spectra, then earthquakes should have a much more energetic PmP phase, with later arrivals be...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%