- journal_title:Geophysics
- Contributor:Hughes A. Djikpesse ; Albert Tarantola
- Publisher:Society of Exploration Geophysicists
- Date:1999-
- Format:text/html
- Language:en
- Identifier:10.1190/1.1444611
- journal_abbrev:Geophysics
- issn:0016-8033
- volume:64
- issue:4
- firstpage:1023
- section:Articles
Estimation of the elastic properties of the crust from surface seismic recordings is of great importance for the understanding of lithology and for the detection of mineral resources. Although in marine reflection experiments only P-waves are recorded, information on shear properties of the medium is contained in multioffset reflection seismograms. Being able to retrieve both dilatational and shear properties gives stronger constraints on the lithology. It is therefore desirable to recover isotropic elastic parameters from multioffset seismograms. Unfortunately, most classical waveform fitting methods used for extracting shear properties of the subsurface are based on a 1-D earth model assumption and on linear approximations of the wave equations. In this paper, a 2.5-D elastic waveform inversion method is used to extract the variations of acoustic impedance and Poisson's ratio from marine multioffset reflection seismograms collected in the Gulf of Mexico area. A complete seismic profile is interpreted, including complex physical phenomena apparent in the data, such as unconsolidated sediment reflections and seismic refraction events. The amplitude of the reflections cannot be explained by one parameter related to the dilatational properties (P-impedance) only, when trying to minimize the least absolute fit between observed and synthetic seismograms. When adding an additional parameter related to shear properties (Poisson's ratio), the fit between observed and synthetic seismograms improves. The resulting 2-D models of P-impedance and Poisson's ratio contrasts are anticorrelated almost everywhere in depth, except where hydrocarbons are present. The estimation of physical P-impedance and Poisson's ratio models by a full waveform fitting allows lithology characterization and, therefore, the delineation of a shale-over-gas sand reservoir.