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Seismic reflectivity of the sediment-covered seafloor: effects of velocity gradients and fine-scale layering

Sidler, Rolf ; Holliger, Klaus

In: Geophysical Journal International, 2010, vol. 181, no. 1, p. 521-531

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    Titre
    • Seismic reflectivity of the sediment-covered seafloor: effects of velocity gradients and fine-scale layering
    Auteur
    • Sidler, Rolf. Institute of Geophysics, University of Lausanne, CH-1015 Lausanne, Switzerland. E-mail: rsidler@gmail.com
    • Holliger, Klaus. Institute of Geophysics, University of Lausanne, CH-1015 Lausanne, Switzerland. E-mail: rsidler@gmail.com
    Type de document
    • Postprint
    Identifiant OAI-PMH
    • oai:doc.rero.ch:299509
    Summary
    Knowledge of the reflectivity of the sediment-covered seabed is of significant importance to marine seismic data acquisition and interpretation as it governs the generation of reverberations in the water layer. In this context pertinent, but largely unresolved, questions concern the importance of the typically very prominent vertical seismic velocity gradients as well as the potential presence and magnitude of anisotropy in soft surficial seabed sediments. To address these issues, we explore the seismic properties of granulometric end-member-type clastic sedimentary seabed models consisting of sand, silt, and clay as well as scale-invariant stochastic layer sequences of these components characterized by realistic vertical gradients of the P- and S-wave velocities. Using effective media theory, we then assess the nature and magnitude of seismic anisotropy associated with these models. Our results indicate that anisotropy is rather benign for P-waves, and that the S-wave velocities in the axial directions differ only slightly. Because of the very high P- to S-wave velocity ratios in the vicinity of the seabed our models nevertheless suggest that S-wave triplications may occur at very small incidence angles. To numerically evaluate the P-wave reflection coefficient of our seabed models, we apply a frequency-slowness technique to the corresponding synthetic seismic wavefields. Comparison with analytical plane-wave reflection coefficients calculated for corresponding isotropic elastic half-space models shows that the differences tend to be most pronounced in the vicinity of the elastic equivalent of the critical angle as well as in the post-critical range. We also find that the presence of intrinsic anisotropy in the clay component of our layered models tends to dramatically reduce the overall magnitude of the P-wave reflection coefficient as well as its variation with incidence angle