GeoSphere 360 3D Reservoir Mapping-While-Drilling Service: Leading to an Improved Characterization of a Fractured/Carbonate Reservoir?
Can we grab the details of three-dimensional (volumetric) fracture network justifying scale-dependent reservoir heterogeneity for a gas-oil-water system?
What will be the approximate reservoir rock (three-dimensional) volume covered by this technique in order to ensure the deduction of Representative Elementary Volume (REV) associated with a Carbonate or a Fractured Reservoir?
With the details on three-dimensional resistivity volumes, will it be feasible to discard ALL kinds of immobile fluids from that of mobile fluids in order to track the resultant three-dimensional gas/oil/water migration pathway towards the production well; and in turn to delineate the best productive zones?
With the details of 4D fluid-movement evaluation, how long could we predict these three-dimensional details of fractured/carbonate reservoir rocks with production time?
With a massive 360 degrees tensor data, if tensors can be asymmetric considering an anisotropic reservoir;
Can we deduce the fracture-matrix interface wetted area precisely?;
Can we deduce the type and direction of imbibition with improved accuracy?;
Can it help to deduce a distinct and reliable relative permeability function for fracture and rock-matrix that can be up-scaled reasonably; and in turn, can we predict water breakthrough & oil recovery from such fractured/carbonate reservoirs with reasonable accuracy (with advanced cloud computing)?
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