Permeability Estimation of Shale Oil Reservoir with Laboratory-derived Data: A Case Study of the Chang 7 Member in Ordos Basin

• Published in: Applied geophysics Vol. 21; no. 3; pp. 440 - 455
• Main Authors: Zhang, Lin, Gao, Li, Ba, Jing, Zhang, Meng-Bo, Carcione, José M., Liu, Wei-Hua
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.09.2024; Springer Nature B.V
• Subjects: Data logging; Earth and Environmental Science; Earth Sciences; Electrical resistivity; Geophysics/Geodesy; Geotechnical Engineering & Applied Earth Sciences; Heterogeneity; Impedance; Logging; Membrane permeability; Natural gas exploration; Nonlinear response; Oil and gas exploration; Oil exploration; Oil reservoirs; Oil shale; P waves; Parameter estimation; Permeability; Physical properties; Porosity; Predictions; Reservoirs; S waves; Sandstone; Sedimentary rocks; Seismic velocities; Shale oil; Shales; Wave velocity; Ordos Basin; China; rock physics experiment; P-wave impedance; shale oil reservoir; permeability; resistivity
• ISSN: 1672-7975; 1993-0658
• DOI: 10.1007/s11770-024-1040-8

The shale oil reservoir within the Yanchang Formations of Ordos Basin harbors substantial oil and gas resources and has recently emerged as the primary focus of unconventional oil and gas exploration and development. Due to its complex pore and throat structure, pronounced heterogeneity, and tight reservoir characteristics, the techniques for conventional oil and gas exploration and production face challenges in comprehensive implementation, also indicating that as a vital parameter for evaluating the physical properties of a reservoir, permeability cannot be effectively estimated. This study selects 21 tight sandstone samples from the Q area within the shale oil formations of Ordos Basin. We systematically conduct the experiments to measure porosity, permeability, ultrasonic wave velocities, and resistivity at varying confining pressures. Results reveal that these measurements exhibit nonlinear changes in response to effective pressure. By using these experimental data and effective medium model, empirical relationships between P-and S-wave velocities, permeability and resistivity and effective pressure are established at logging and seismic scales. Furthermore, relationships between P-wave impedance and permeability, and resistivity and permeability are determined. A comparison between the predicted permeability and logging data demonstrates that the impedance–permeability relationship yields better results in contrast to those of resistivity–permeability relationship. These relationships are further applied to the seismic interpretation of shale oil reservoir in the target layer, enabling the permeability profile predictions based on inverse P-wave impedance. The predicted results are evaluated with actual production data, revealing a better agreement between predicted results and logging data and productivity.