Simulation of Multiphase Flow in Subsurface Porous Media for Low-Carbon Energy Systems
local_shippingShip to Me
Overview
Simulation of Multiphase Flow in Subsurface Porous Media for Low-Carbon Energy Systems addresses the urgent need for pore-scale rigor in energy-transition workflows. As CO₂ and H₂ injection, groundwater management, contaminant remediation, and geothermal operations expand, decision-quality predictions hinge on resolving interfacial physics, wettability, capillarity, and transport in complex rock microstructures. This reference equips researchers and practicing engineers to interpret, calibrate, and upscale pore-scale phenomena into reliable macroscopic parameters that constrain reservoir simulation and risk assessment for low-carbon deployments. Contents integrate foundational theory with a method-centered architecture. Digital rock reconstruction introduces multiscale, hybrid, and deep-learning approaches for realistic pore geometries. Multiphase flow theory consolidates interfacial tension, wettability, capillary pressure, nanoscale transport, and extended governing equations. Dedicated chapters cover six leading techniques: molecular dynamics for kerogen nanopores and H₂/water transport; lattice Boltzmann color-gradient and Shan-Chen models for methane-water and CO₂-water dynamics; pore-network modeling with thin-film physics across Berea and tight sandstones; and CFD-based volume-of-fluid, level-set, and phase-field formulations with explicit numerical schemes and boundary conditions. Each chapter shares a consistent scaffold--principles, algorithms, and reproducible case studies--supported by color figures, equations, and data to enable independent use. Simulation of Multiphase Flow in Subsurface Porous Media for Low-Carbon Energy Systems empowers end users to select appropriate methods, avoid modeling pitfalls, and generate actionable outputs such as relative permeability, entry pressures, and displacement efficiencies. Readers gain transferable workflows, benchmarking insight, and transparent assumptions to de-risk pore- to core-scale upscaling for CO₂/H₂ storage, waterflood optimization, and reactive environmental processes. Ancillary materials include MD code and simulation videos, enhancing comprehension and accelerating adoption in research and practice.
This item is Non-Returnable
Customers Also Bought
Details
- ISBN-13: 9780443542312
- ISBN-10: 0443542317
- Publisher: Elsevier
- Publish Date: February 2027
- Shipping Weight: 0.99 pounds
- Page Count: 375
Related Categories
