2D characterization of near‐surface : surface‐wave dispersion inversion versus refraction tomography

The joint study of pressure (P‐) and shear (S‐) wave velocities ( and ), as well as their ratio ( ), has been used for many years at large scales but remains marginal in near‐surface applications. For these applications, and are generally retrieved with seismic refraction tomography combining P and...

Full description

Saved in:
Bibliographic Details
Published in:Near surface geophysics (Online) 2015-08, Vol.13 (4), p.315-332
Main Authors: Pasquet, Sylvain, Bodet, Ludovic, Longuevergne, Laurent, Dhemaied, Amine, Camerlynck, Christian, Rejiba, Fayçal, Guérin, Roger
Format: Article
Language:English
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The joint study of pressure (P‐) and shear (S‐) wave velocities ( and ), as well as their ratio ( ), has been used for many years at large scales but remains marginal in near‐surface applications. For these applications, and are generally retrieved with seismic refraction tomography combining P and SH (shear‐horizontal) waves, thus requiring two separate acquisitions. Surface‐wave prospecting methods are proposed here as an alternative to SH‐wave tomography in order to retrieve pseudo‐2D sections from typical P‐wave shot gathers and assess the applicability of combined P‐wave refraction tomography and surface‐wave dispersion analysis to estimate ratio. We carried out a simultaneous P‐ and surface‐wave survey on a well‐characterized granite‐micaschists contact at Plœmeur hydrological observatory (France), supplemented with an SH‐wave acquisition along the same line in order to compare results obtained from SH‐wave refraction tomography and surface‐wave profiling. Travel‐time tomography was performed with P‐ and SH‐ wave first arrivals observed along the line to retrieve and models. Windowing and stacking techniques were then used to extract evenly spaced dispersion data from P‐wave shot gathers along the line. Successive 1D Monte Carlo inversions of these dispersion data were performed using fixed V p values extracted from the model and no lateral constraints between two adjacent 1D inversions. The resulting 1D models were then assembled to create a pseudo‐2D section, which appears to be correctly matching the general features observed on the section. If the pseudo‐section is characterized by strong velocity uncertainties in the deepest layers, it provides a more detailed description of the lateral variations in the shallow layers. Theoretical dispersion curves were also computed along the line with both and models. While the dispersion curves computed from models provide results consistent with the coherent maxima observed on dispersion images, dispersion curves computed from models are generally not fitting the observed propagation modes at low frequency. Surface‐wave analysis could therefore improve V s models both in terms of reliability and ability to describe lateral variations. Finally, we were able to compute V P / V S sections from both and models. The two sections present similar features, but the section obtained from shows a higher lateral resolution and is consistent with the features observed on electrical resistivity tomography, thus validati
ISSN:1569-4445
1873-0604
DOI:10.3997/1873-0604.2015028