Petrophysical Characterization and Fluids Transport in Unconventional Reservoirs presents a comprehensive look at these new methods and technologies for the petrophysical characterization of unconventional reservoirs, including recent theoretical advances and modeling on fluids transport in unconventional reservoirs. The book is a valuable tool for geoscientists and engineers working in academia and industry. Many novel technologies and approaches, including petrophysics, multi-scale modelling, rock reconstruction and upscaling approaches are discussed, along with the challenge of the development of unconventional reservoirs and the mechanism of multi-phase/multi-scale flow and transport in these structures.
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Table of Contents
Part 1 Petrophysical Characterization 1. Characterizing Pore Size Distributions of Shale 2. Petrophysical Characterization of the Pore Structure of Coal 3. Characterization of Petrophysical Properties in Tight Sandstone Reservoirs 4. Multifractal Analysis of Pore Structure of Tight Oil Reservoirs Using Low-Field NMR Measurements 5. Investigation and Quantitative Evaluation of Organic-Related Pores in Unconventional Reservoirs 6. Permeability of Fractured Shale and Two-Phase Relative Permeability in Fractures 7. Pore Structure, Wettability, and Their Coupled Effects on Tracer-Containing Fluid Migration in Organic-Rich Shale 8. Tight Rock Wettability and Its Relationship With Petrophysical Properties
Part 2 Porous Flow Dynamics 9. Flow Mechanism of Fractured Low-Permeability Reservoirs 10. Heat Transfer in Enhanced Geothermal Systems: Thermal-Hydro-Mechanical Coupled Modeling 11. Pore-Scale Modeling and Simulation in Shale Gas Formations 12. High-Pressure Methane Adsorption in Shale 13. Coal Permeability Modeling Considering Nonconstant Vertical Stress Condition 14. Dynamic Gas Flow in Coals and Its Evaluation 15. Multiphysical Flow Behavior in Shale and Permeability Measurement by Pulse-Decay Method
