This paper describes the refraction statics processing based on tomographic inversion of a 503km 2 subset of a modern marine 3D seismic dataset acquired in very shallow waters offshore Qatar. The objective of the seismic survey was imaging of the Mesozoic interval from 0.4 -1.8 seconds two way travel time below sea level. Characteristic for the study area is the presence of local shoal bodies, often associated with coral reefs at sea bottom and in the near surface below sea bottom. These features can have a significant effect on the imaging of seismic data and therefore the prospectivity assessment of the exploration area as their typically high velocity introduces distortions in the timing of events, i.e. false structures might be generated or true structures suppressed. Compensating for the reef structures in the statics model results in a more accurate image of the subsurface.This was achieved by applying first-arrival travel time tomography to obtain the shallow velocity information needed to calculate refraction statics corrections. Refraction statics tomography uses the first break travel time picks of the seismic data to derive a velocity model of the near surface. This velocity model is then used to generate static shifts to correct the data to a final datum plane using a known replacement velocity, thereby removing the velocity variation caused by the sea bottom and near surface features. The tomographic inversion algorithm for land data was adapted to marine data by including a new option to freeze the water column velocity, which should be constant and not taken into account in the velocity updates. Refraction statics tomography is superior to conventional refraction statics because the inverted velocity model reveals the lateral and vertical velocity variations in the near surface.The dense shot and receiver spacing of this data set provided a large number of first break picks for the tomographic inversion process and resulted in a stable near surface velocity model. The computed static shifts corrected for some of the time shifts observed below the sea bottom features. The application of refraction statics tomography in this study provided an improved subsurface image compared to the original processing.
Borehole seismic surveys provide vital depth and velocity parameters needed to link surface seismic data with downhole log and well data. Furthermore they can deliver high-resolution subsurface images, detect anisotropy caused by natural fractures and help to monitor fluid movement depending on the chosen survey geometry. A borehole seismic survey, whether simple checkshots or a more complex VSP, is usually part of the initial data acquisition program in exploration and appraisal wells, but it is not uncommon that only the depth-time data from such a survey is used in seismic interpretation. This paper is intended for geoscientists working on subsurface projects to highlight information that can be gleaned from a VSP wavefield in addition to only a depth-time correlation.
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