Two models with different area and 3D volumetric grid size dimension of the E6 oil-bearing structure were built. The bigger model should allow visualization of complete migration of CO2 plume within the developed 3D grid model using fluid-flow simulation (cell size 500 m). The smaller model is focused on the uppermost part of the Cambrian Series 3 Deimena Formation reservoir close to the drilled well, assuming that CO2 injection will take place in this area. The model with a finer gridding (cell size 30 m) was adopted for seismic numerical modelling. The grid size of this in the model was reduced as much as possible to satisfy seismic modelling needs.

3D Geological and Petrophysical Numerical Models of E6 Structure for CO2 Storage in the Baltic Sea

Forlin E.;
2017-01-01

Abstract

Two models with different area and 3D volumetric grid size dimension of the E6 oil-bearing structure were built. The bigger model should allow visualization of complete migration of CO2 plume within the developed 3D grid model using fluid-flow simulation (cell size 500 m). The smaller model is focused on the uppermost part of the Cambrian Series 3 Deimena Formation reservoir close to the drilled well, assuming that CO2 injection will take place in this area. The model with a finer gridding (cell size 30 m) was adopted for seismic numerical modelling. The grid size of this in the model was reduced as much as possible to satisfy seismic modelling needs.
2017
3D geological modelling; Baltic Sea; Cambrian Series 3 Deimena Formation
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14083/5424
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