When There Is No Offset: A Demonstration of Seismic Diffraction Imaging and Depth‐Velocity Model Building in the Southern Aegean Sea

Abstract: A vast majority of marine geological research is based on academic seismic data collected with single-channel systems or short-offset multichannel seismic cables, which often lack reflection moveout for conventional velocity analysis. Consequently, our understanding of Earth processes often relies on seismic time sections, which hampers quantitative analysis in terms of depth, formation thicknesses, or dip angles of faults. In order to overcome these limitations, we present a robust diffraction extraction sche… Show more

“…Future studies should concentrate on mitigating the effect of out‐of‐plane diffractions for focusing migration velocity analysis from 2D seismic profiles (e.g., Preine et al., 2020). This could be achieved by weighting the focusing analysis toward continuous diffraction generating structures such as faults, or deeper diffractors that are less biased by not being exactly in‐plane.…”

“…Identical migrations are performed for the full‐wavefield and diffraction images so that the geometry of both images is comparable (Figure 3). The diffraction images in this study are presented as the energy (squared envelope) of the diffraction image (as in, e.g., Preine et al., 2020).…”

“…A classic application for diffraction imaging is to derive migration velocity fields by focusing analysis of the diffracted wavefield (e.g., Decker et al., 2017; Fomel et al., 2007; Preine et al., 2020). Under the correct migration velocity, diffractions will collapse (focus) to a point at their apex.…”

“…The illumination of seismic reflectors depends on the local dip of the reflector and the geometry of the receiver array. Diffractions, however, are 3D phenomena, fully illuminated from all angles even by single-channel, zero-offset data (Figure 1a and Preine et al, 2020). This means that 2D diffraction images will suffer more strongly from out-of-plane energy than corresponding 2D reflection images.…”

“…Diffraction imaging works by separating the reflected and diffracted wavefields and migrating only the diffracted component, producing an image of these small-scale heterogeneities (Klem-Musatov et al, 2016;Schwarz, 2019b). Contrary to reflections, the radiation pattern of diffractions is independent of the dip (Figure 1), meaning that they can be fully illuminated even by short-offset or zero-offset receiver arrays (Preine et al, 2020). Combined with the general smaller scale of diffractors compared to reflectors, this radial spreading means that for a given seismic source the recorded diffracted wavefield tends to be significantly weaker and have higher frequency content than the reflected wavefield.…”

Seismic Diffraction Imaging to Characterize Mass‐Transport Complexes: Examples From the Gulf of Cadiz, South West Iberian Margin

“…Future studies should concentrate on mitigating the effect of out‐of‐plane diffractions for focusing migration velocity analysis from 2D seismic profiles (e.g., Preine et al., 2020). This could be achieved by weighting the focusing analysis toward continuous diffraction generating structures such as faults, or deeper diffractors that are less biased by not being exactly in‐plane.…”

“…Identical migrations are performed for the full‐wavefield and diffraction images so that the geometry of both images is comparable (Figure 3). The diffraction images in this study are presented as the energy (squared envelope) of the diffraction image (as in, e.g., Preine et al., 2020).…”

“…A classic application for diffraction imaging is to derive migration velocity fields by focusing analysis of the diffracted wavefield (e.g., Decker et al., 2017; Fomel et al., 2007; Preine et al., 2020). Under the correct migration velocity, diffractions will collapse (focus) to a point at their apex.…”

“…The illumination of seismic reflectors depends on the local dip of the reflector and the geometry of the receiver array. Diffractions, however, are 3D phenomena, fully illuminated from all angles even by single-channel, zero-offset data (Figure 1a and Preine et al, 2020). This means that 2D diffraction images will suffer more strongly from out-of-plane energy than corresponding 2D reflection images.…”

“…Diffraction imaging works by separating the reflected and diffracted wavefields and migrating only the diffracted component, producing an image of these small-scale heterogeneities (Klem-Musatov et al, 2016;Schwarz, 2019b). Contrary to reflections, the radiation pattern of diffractions is independent of the dip (Figure 1), meaning that they can be fully illuminated even by short-offset or zero-offset receiver arrays (Preine et al, 2020). Combined with the general smaller scale of diffractors compared to reflectors, this radial spreading means that for a given seismic source the recorded diffracted wavefield tends to be significantly weaker and have higher frequency content than the reflected wavefield.…”

Seismic Diffraction Imaging to Characterize Mass‐Transport Complexes: Examples From the Gulf of Cadiz, South West Iberian Margin

Systematic literature review on seismic diffraction imaging

Risks and uncertainties in carbon capture, transport, and storage projects: A comprehensive review