Understanding Geologic Carbon Sequestration and Gas Hydrate from Molecular Simulation 1st Edition

Capture the cutting edge of subsurface science with Understanding Geologic Carbon Sequestration and Gas Hydrate from Molecular Simulation, 1st Edition by Yongchen Song; Cong Chen; Wenfeng Hu. This authoritative volume bridges molecular-level modeling and real-world applications, serving researchers, reservoir engineers, and graduate students seeking rigorous insight into carbon capture and methane-hydrate systems.

Discover how advanced molecular simulation techniques—molecular dynamics, Monte Carlo methods, and multiscale modeling—reveal pore-scale behaviors that control CO2 trapping, hydrate formation, and gas migration. Clear explanations of thermodynamics, phase behavior, and transport phenomena are paired with practical case studies to show how simulations inform field-scale geologic carbon sequestration and hydrate exploitation strategies across North America, Europe, and Asia.

Packed with actionable findings and methodological guidance, this book helps professionals translate atomistic results into improved reservoir modeling, risk assessment, and climate-mitigation planning. It emphasizes environmental safety, long-term storage integrity, and efficient resource recovery—making it essential for policymakers, industry practitioners, and academic labs working on CO2 storage, methane hydrate stability, and energy transition challenges.

Whether you’re advancing research or implementing projects, this book provides the theoretical foundation and simulation workflows needed to tackle subsurface complexity with confidence. Add Understanding Geologic Carbon Sequestration and Gas Hydrate from Molecular Simulation to your library for a practical, scientifically robust roadmap to molecular-scale solutions for global carbon management and gas-hydrate science.

Note: eBooks do not include supplementary materials such as CDs, access codes, etc.