The test reprocessing achieved a major improvement in imaging beneath the basalts that had previously obscured the deeper geology. Following this successful trial on the NWZ96 data the entire Fugro 2D non-exclusive database in the region was re-processed. The surveys had been recorded with broadly similar acquisition parameters, and the processing was carried out using a generic scheme with similar parameters to ensure compatibility between datasets. This re-processed regional seismic dataset now allows a much more detailed interpretation of the sub-basalt section. But to take this further, additional data are needed to model the basin structure.
As part of their multi-client geophysical data library, Fugro Gravity & Magnetic Services (FGMS) have available a merged high-resolution aeromagnetic dataset extending across and beyond the area covered by the 2D seismic. This consists of 278,000 line kilometres of data with a predominant 500m line spacing. These data are particularly useful as a screening tool to identify the extent of the basalts, igneous centres and sedimentary basins, enabling the geometry, depth and magnetic properties of sub-surface rock structures to be mapped. The major features and trends of the area can be observed at a glance on such a magnetic anomaly map.
The magnetic data can however be used to help in interpretation of the reprocessed seismic data. The top of the magnetic basement can be picked on the reprocessed seismic lines when the seismic and magnetic data are integrated. To construct this model, FGMS proprietary Potential Fields Software was used. A magnetic susceptibility value is assigned to each stratigraphic layer, which has previously been interpreted from the seismic data. In the study area the sediments can be regarded as magnetically transparent, their susceptibility being several orders of magnitude lower than either the volcanics or crystalline basement.
Anomaly
The magnetic anomaly generated by the combined seismic/magnetic structural model is compared to the observed magnetic anomaly. The structural model is then “fine tuned” to achieve a best fit with the observed and calculated magnetic anomalies. The magnetic data therefore constrain the seismic travel-time basement pick, which would otherwise be difficult to interpret using the seismic data alone, given the limited well information available in the region. The success of this 2D modelling on selected seismic lines gave the impetus to undertake full 3D inversion of the magnetic data, permitting the generation of a depth to magnetic basement model across the entire region.
The re-processing of the seismic data and the modelling of the magnetic data has produced a dataset which greatly assists evaluation of the sub-basalt section and provides a significantly improved dataset. The improvement in data quality has helped to interpret the thickness of the volcanic units, to image potential hydrocarbon plays in the sub-basalt sediments, and to generate a depth-to-magnetic-basement model across the region. This powerful exploration dataset has been created using modern processing techniques but using “heritage” data, showing the potential improvements possible in older datasets that may often lie fallow. This process has also delineated basin structure, enabling tectonic geologists to model more accurately the structure and subsidence history of the NW European continental margin. The commercial advantage of this is clear. We are now able to sample this precious data archive and retrieve information in ways that are analogous to those sound engineers use to re-master acoustic recordings on shellac discs by long-dead musical geniuses of the past.