Abstract
Subsalt seismic imaging is particularly difficult due to the complex overburdens, caused by the movement of salt that usually results in steeply dipping structures, which along with strong lateral velocity contrast at the sedimentssalt interface distort the structural position and the stratigraphic resolution of the subsalt reservoirs. Despite it was proven that two-way wave equation migration provides the best results illuminating these reservoirs, it has huge computational cost, especially in three dimensions. One-way wave equation (OWWE) migration techniques are good alternative in this case as providing the acceptable quality of seismic sections with an appropriate computational cost. To know the advantages and limitations of the OWWE techniques in subsalt imaging, three classical OWWE algorithms were evaluated for depth migration of prestack data (PSDM): phase-shift-plus-interpolation (PSPI), splitstep Fourier (SSF), and Fourier finite-difference (FFD). These algorithms were tested with three different fully elastic synthetic models which simulates the structural complexity showed in subsalt plays. It was concluded that FFD gives very accurate results when the lateral velocity variation was strong with acceptable computational cost. The PSPI provided the best quality results but required about twice the computer time needed for FFD, and SSF was the fastest but clearly the least accurate.
Highlights
Salt flow frequently leads to strongly deformed formations with steeply dipping structures that present significant challenges for the seismic migration methods
The analysis of the results showed that splitstep Fourier (SSF) method has serious problems in the presence of strong lateral velocity variations, and especially when layers have a dip angle greater than 45 degrees
The performance of One-way wave equation (OWWE) methods is seriously affected by the steeply dipping structures generated by the salt movement
Summary
Salt flow frequently leads to strongly deformed formations with steeply dipping structures that present significant challenges for the seismic migration methods. Prestack depth migration methods are the most commonly used in structurally complex areas. These are usually put into two separate categories – ray-based methods and wave field extrapolation-based methods (Han, 1998), both derived from the acoustic or elastic wave equation. The ray-based prestack Kirchhoff migration is still the most popular as it is costeffective and can image most of the complex structures. This technique has some intrinsic limitations preventing it from handling extremely complex structures characterized by steep dips caused by salt movement (Mulder and Plessix, 2004). The multi-path ray tracing in salt structures may yield improper travel times, causing poor subsurface imaging
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