Geophysics and the Energy Transition

Geophysics and the Energy Transition

Davis, Tom; Wilson, Malcolm; Landro, Martin

Elsevier - Health Sciences Division

11/2024

475

Mole

9780323959414

Pré-lançamento - envio 15 a 20 dias após a sua edição

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Section 1: The Energy Transition:
1. Introduction to the Energy Transition
2. Technologies Involved in the Energy Transition
3. Preventing CO2 from Fossil Fuels from Reaching the Atmosphere
4. Subsurface CCS

Section 2: Selecting Sites and Ensuring Effective Storage
5. An Engineering Perspective on the Need for Effective Management of Subsurface Carbon Storage
6. Rock Physics for Subsurface CCS Via Laboratory and Field Scale Data
7. The Geochemistry of Geosequestration
8. The Geomechanics of Subsurface CCS
9. Geophysical Technologies for CO2 Monitoring
10. CO2 and Hydrogen Storage: Field Studies

Section 3: Site Studies of Advanced Technology and Broad Application of These Technologies
11. Weyburn Field, Williston Basin: Case Study
12. Vacuum Field, Permian Basin: Case Study
13. Northern Lights Project, Norway: CCS in Industrial Transformation
14. Aquistore Project, Canada: Case Study
15. New CCS projects in the Williston Basin, North Dakota, Montana: Case Study

Section 4: Moving Forward
16. Expanding CCS opportunities Into Hallow Zones
17. Storage and Monitoring in Volcanic Zones
18. Lessons learned from Sleipner, Algeria, Snovhit, Ketzin, Quest, Decatur, Barendrecht, UK initiatives, Germany Oxyfuel, Kemper Co. Gasification.
19. Evolution of the Knowledge Base and Lessons Learned for Future CCS Subsurface Projects
20. Future Challenges and Opportunities for Geoscientists and Engineers

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3D mapping tools; 4D seismic; Acoustics; Advanced geophysical monitoring; Applied geology; Applied geophysics; Applied mechanics; Aquistore; Automated data collection; Biofuel; Buoyant gas; CCS; CCUS; CH4; CO2; CO2 EOR; CO2 capture; CO2 sensitivity analysis; CO2 sequestration; CO2 storage; CO2 use; Caprock; Carbon capture and storage; Carbon capture and storage (CCS); Carbon capture and underground storage; Carbon capture technologies; Carbon capture utilization and storage (CCUS); Carbon dioxide; Carbon free energy; Carbon sequestration; Carbon storage; Careers; Chemomechanics; Climate change; Climate policy; Collaboration; Compact volumetric phased array; Computational geophysical acquisition; Conformance; Containment; Controlled source electromagnetics; Converted shear wave (PS); Cost of CCS; Cost of CO2 capture; Cost of CO2 storage; Cost of CO2 transport; Cost of carbon capture sequestration; Cost of the survey; DAC; Data integration; Decarbonization; Deep saline formations; Density; Distributed acoustic sensing; Dynamic reservoir characterization; Earth sciences; Earthquake risks; Economics; Elastic; Electromagnetics; Energy and climate change; Energy policy; Energy sustainability; Energy systems; Energy transition; Energy types; Environmental chemical engineering; Environmental monitoring; Environmental science; Ethanol; Facies-based inversion; Fiber optic; Fiber optics; Finance; Fixed seismic arrays; Flow measurement; Fluid migration; Formation; Formation permeability; Formation porosity; Fourth Industrial Revolution; Future opportunities; GHG; Geologic hydrogen; Geological storage; Geomechanical; Geophone network; Geophysics; Geosequestration; Geothermal; H2; Hydrogen; Injection; Innovation; Integrated reservoir characterization; Interactive data visualization; Inverse theory; Leak detection; Low temperature aqueous geochemistry; Machine learning