A new approach to petroelastic modeling of carbonate rocks using an extended pore-space stiffness method, with application to a carbonate reservoir in Central Luconia, Sarawak, Malaysia

Babasafari, A.A. and Bashir, Y. and Ghosh, D.P. and Salim, A.M.A. and Janjuhah, H.T. and Kazemeini, S.H. and Kordi, M. (2020) A new approach to petroelastic modeling of carbonate rocks using an extended pore-space stiffness method, with application to a carbonate reservoir in Central Luconia, Sarawak, Malaysia. Leading Edge, 39 (8). 592a1-592a10.

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Abstract

Pore geometry plays an important role in the elastic response of carbonate rocks. Diagenetic processes in carbonate sediments generate a range of pore-type distributions. Hence, the petroelastic modeling (PEM) of carbonate rocks is more complex than for clastics. Petrophysical properties connect to elastic properties through PEM or, in general terms, rock-physics modeling. Pore types cause variation in P-wave velocity-up to 40 for a given porosity. A variety of pore types with different aspect ratios such as vuggy, moldic, interparticle, intraparticle, fracture, and crack makes the porosity-velocity relationship complex, and empirical models fail to handle it properly. We propose a new, easy-to-implement approach for PEM of carbonate rocks that leads to more accurate elastic properties estimation. It offers a novel PEM method that reduces the number of defined parameters and equations. In it, the Xu-Payne rock-physics modeling equations are replaced with an extended pore-space stiffness equation. Instead of including a pore's aspect ratio as is done when using the Xu-Payne inclusion model formulation, in our proposed technique only the appropriate value of pore-space stiffness for each pore type is considered, together with the corresponding volume fraction of pore types. However, parameters are optimized by calibrating the estimated elastic properties with corresponding information from well-log measurements. This inclusion model yields acceptable predictions of elastic properties at wells that do not have measured elastic logs. The method was tested using well data from a carbonate reservoir in Central Luconia, offshore Sarawak, Malaysia. Here, one well has a complete suite of log data needed to calibrate the model. The calibrated model was then used to predict the missing shear velocity log in the other well. Next, simultaneous elastic seismic inversion was performed on 3D seismic data covering the area of the carbonate reservoir, and elastic property volumes (acoustic impedance and VP/VS ratio) were estimated. From these results, a posterior probability distribution of stiff pore types was determined, which validated the outcome of this approach using a blind test. © 2020 by The Society of Exploration Geophysicists.

Item Type: Article
Impact Factor: cited By 2
Uncontrolled Keywords: Acoustic impedance; Aspect ratio; Carbonates; Elasticity; Offshore oil well production; Petroleum reservoirs; Petrophysics; Porosity; Probability distributions; Sedimentary rocks; Seismic waves; Seismology; Shear flow; Stiffness; Wave propagation; Well logging, Carbonate reservoir; Carbonate sediments; Diagenetic process; Petroelastic modeling; Petrophysical properties; Porosity-velocity relationship; Rock physics model; Stiffness equations, Carbonation, calibration; carbonate rock; data inversion; elastic property; seismic data; seismic velocity, Central Luconia; East Malaysia; Malaysia; Pacific Ocean; Sarawak; South China Sea
Depositing User: Ms Sharifah Fahimah Saiyed Yeop
Date Deposited: 25 Mar 2022 06:34
Last Modified: 25 Mar 2022 06:34
URI: http://scholars.utp.edu.my/id/eprint/30120

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