Geomechanical in CO2 Storage Facilities

✍ Scribed by Gilles Pijaudier-Cabot (editor), Jean-michel Pereira (editor)

Publisher: Iste/Hermes Science Pub
Year: 2012
Tongue: English
Leaves: 248
Series: Civil Engineering and Geomechanics
Edition: New
Category: Library

No coin nor oath required. For personal study only.

✦ Synopsis

CO2 capture and geological storage is seen as the most effective technology to rapidly reduce the emission of greenhouse gases into the atmosphere. Up until now and before proceeding to an industrial development of this technology, laboratory research has been conducted for several years and pilot projects have been launched. So far, these studies have mainly focused on transport and geochemical issues and few studies have been dedicated to the geomechanical issues in CO2 storage facilities. The purpose of this book is to give an overview of the multiphysics processes occurring in CO2 storage facilities, with particular attention given to coupled geomechanical problems.
The book is divided into three parts. The first part is dedicated to transport processes and focuses on the efficiency of the storage complex and the evaluation of possible leakage paths. The second part deals with issues related to reservoir injectivity and the presence of fractures and occurrence of damage. The final part of the book concerns the serviceability and ageing of the geomaterials whose poromechanical properties may be altered by contact with the injected reactive fluid.

✦ Table of Contents

Title Page
Contents
Preface
PART 1. TRANSPORT PROCESSES
Chapter 1. Assessing Seal Rock Integrity for CO2 Geological Storage Purposes
1.1. Introduction
1.2. Gas breakthrough experiments in water-saturated rocks
1.3. Interfacial properties involved in seal rock integrity
1.3.1. Brine-gas IFT
1.3.2. Wetting behavior
1.4. Maximum bottomhole pressure for storage in a depleted hydrocarbon reservoir
1.5. Evidences for capillary fracturing in seal rocks
1.6. Summary and prospects
1.7. Bibliography
Chapter 2. Gas Migration through Clay Barriers in the Context of Radioactive Waste Disposal: Numerical Modeling of an In Situ Gas Injection Test
2.1. Introduction
2.2. Field experiment description
2.3. Boundary value problem
2.3.1. 1D and 3D geometry and boundary conditions
2.3.2. Hydraulic model
2.3.3. Hydraulic parameters
2.4. Numerical results
2.4.1. 1D modeling
2.4.2. 3D modeling
2.5. Discussion and conclusions
2.6. Bibliography
Chapter 3. Upscaling Permeation Properties in Porous Materials from Pore Size Distributions
3.1. Introduction
3.2. Assembly of parallel pores
3.2.1. Presentation
3.2.2. Permeability
3.2.3. Case of a sinusoidal multi-modal pore size distribution
3.3. Mixed assembly of parallel and series pores
3.3.1. Presentation
3.3.2. Permeability
3.4. Comparisons with experimental results
3.4.1. Electrical fracturing tests
3.4.2. Measurement of the pore size distribution
3.4.3. Model capabilities to predict permeability and comparisons with experiments
3.5. Conclusions
3.6. Acknowledgments
3.7. Bibliography
PART 2. FRACTURE, DEFORMATION AND COUPLED EFFECTS
Chapter 4. A Non-Local Damage Model for Heterogeneous Rocks – Application to Rock Fracturing Evaluation Under Gas Injection Conditions
4.1. Introduction
4.2. A probabilistic non-local model for rock fracturing
4.3. Hydromechanical coupling scheme
4.4. Application example and results
4.4.1. Effect of Weibull modulus
4.5. Conclusions and perspectives
4.6. Acknowledgments
4.7. Bibliography
Chapter 5. Caprock Breach: A Potential Threat to Secure Geologic Sequestration of CO2
5.1. Introduction
5.2. Caprock flexure during injection
5.2.1. Numerical results for the caprock–geologic media interaction
5.3. Fluid leakage from a fracture in the caprock
5.3.1. Numerical results for fluid leakage from a fracture in the caprock
5.4. Concluding remarks
5.5. Acknowledgment
5.6. Bibliography
Chapter 6. Shear Behavior Evolution of a Fault due to Chemical Degradation of Roughness: Application to the Geological Storage of CO2
6.1. Introduction
6.2. Experimental setup
6.3. Roughness and chemical attack
6.4. Shear tests
6.5. Peak shear strength and peak shear displacement: Barton’s model
6.6. Conclusion and perspectives
6.7. Acknowledgment
6.8. Bibliography
Chapter 7. CO2 Storage in Coal Seams: Coupling Surface Adsorption and Strain
7.1. Introduction
7.2. Poromechanical model for coal bed reservoir
7.2.1. Physics of adsorption-induced swelling of coal
7.2.2. Assumptions of model for coal bed reservoir
7.2.3. Case of coal bed reservoir with no adsorption
7.2.4. Derivation of constitutive equations for coal bed reservoir with adsorption
7.3. Simulations
7.3.1. Simulations at the molecular scale: adsorption of carbon dioxide on coal
7.3.2. Simulations at the scale of the reservoir
7.3.3. Discussion
7.4. Conclusions
7.5. Bibliography
PART 3. AGING AND INTEGRITY
Chapter 8. Modeling by omogenization of the Long erm Rock Dissolution and eomechanical Effects
8.1. Introduction
8.2. Microstructure and modeling by homogenization
8.3. Homogenization of the H-M-T problem
8.3.1. Formulation of the problem at the microscopic scale
8.3.2. Asymptotic developments method
8.3.4. Summary of the macroscopic “H-M-T model”
8.4. Homogenization of the C-M problem
8.4.1. Formulation of the problem at the microscopic scale
8.4.2. Homogenization
8.4.3. Summary of the macroscopic “C-M model”
8.5. Numerical computations of the time degradation of the macroscopic rigidity tensor
8.5.1. Definition of the problem
8.5.2. Results and discussion
8.6. Conclusions
8.7. Acknowledgment
8.8. Bibliography
Chapter 9. Chemoplastic Modeling of Petroleum Cement Paste under Coupled Conditions
9.1. Introduction
9.2. General framework for chemo-mechanical modeling
9.2.1. Phenomenological chemistry model
9.3. Specific plastic model for petroleum cement paste
9.3.1. Elastic behavior
9.3.2. Plastic pore collapse model
9.3.3. Plastic shearing model
9.4. Validation of model
9.5. Conclusions and perspectives
9.6. Bibliography
Chapter 10. Reactive Transport Modeling of CO2 Through Cementitious Materials Under Supercritical Boundary Conditions
10.1. Introduction
10.2. Carbonation of cement-based materials
10.2.1. Solubility of the supercritical CO2 in the pore solution
10.2.2. Chemical reactions
10.2.3. Carbonation of CH
10.2.4. Carbonation of C-S-H
10.2.5. Porosity change
10.3. Reactive transport modeling
10.3.1. Field eq
10.3.2. Transport of the liquid phase
10.3.3. Transport of the gas phase
10.3.4. Transport of aqueous species
10.4. Simulation results and discussion
10.4.1. Sandstone-like co
10.4.2. Limestone-like conditions
10.4.3. Study of CO2 concentration and initial porosity
10.4.4. Supercritical boundary conditions
10.5. Conclusion
10.6. Acknowledgment
10.7. Bibliography
Chapter 11. Chemo-Poromechanical Study of Wellbore Cement Integrity
11.1. Introduction
11.2. Poromechanics of cement carbonation in the context of CO2 storage
11.2.1. Context and definitions
11.2.2. Chemical reactions
11.2.3. Chemo-poromechanical behaviour
11.2.4. Balance equations
11.3. Application to wellbore cement
11.3.1. Description of the problem
11.3.2. Initial state and boundary conditions
11.3.3. Illustrative results
11.4. Conclusion
11.5. Acknowledgments
11.6. Bibliography
List of Authors
Index

📜 SIMILAR VOLUMES

Geomechanics in CO Storage Facilities

📁 Geomechanics in CO Storage Facilities

📂 Library 📅 2012 🏛 Wiley-ISTE 🌐 English

<p>CO2 capture and geological storage is seen as the most effective technology to rapidly reduce the emission of greenhouse gases into the atmosphere. Up until now and before proceeding to an industrial development of this technology, laboratory research has been conducted for several years and pilo

Microseismic Monitoring and Geomechanica

📁 Microseismic Monitoring and Geomechanical Modelling of CO2 Storage in Subsurface Reservoirs

✍ James P. Verdon (auth.) 📂 Library 📅 2012 🏛 Springer-Verlag Berlin Heidelberg 🌐 English

<p>This thesis presents an impressive summary of the potential to use passive seismic methods to monitor the sequestration of anthropogenic CO2 in geologic reservoirs. It brings together innovative research in two distinct areas – seismology and geomechanics – and involves both data analysis and num

Microseismic Monitoring and Geomechanica

📁 Microseismic Monitoring and Geomechanical Modelling of CO2 Storage in Subsurface Reservoirs

✍ James P. Verdon (auth.) 📂 Library 📅 2012 🏛 Springer-Verlag Berlin Heidelberg 🌐 English

Geotechnical Engineering for Mine Waste

📁 Geotechnical Engineering for Mine Waste Storage Facilities

✍ Geoffrey Blight 📂 Library 📅 2010 🏛 CRC Press 🌐 English

The book is a comprehensive treatment of the application of geotechnical engineering to site selection, site exploration, design, operation and closure of mine waste storage facilities.The level and content are suitable as a technical source and reference for practising engineers engaged both in the

Geotechnical Engineering for Mine Waste

📁 Geotechnical Engineering for Mine Waste Storage Facilities

✍ Geoffrey E. Blight 📂 Library 📅 2010 🏛 CRC Press 🌐 English

The book is a comprehensive treatment of the application of geotechnical engineering to site selection, site exploration, design, operation and closure of mine waste storage facilities.<BR>The level and content are suitable as a technical source and reference for practising engineers engaged both in

Geotechnical Engineering for Mine Waste

📁 Geotechnical Engineering for Mine Waste Storage Facilities

✍ Geoffrey E. Blight (Author) 📂 Library 📅 2009 🏛 CRC Press

<p>The book is a comprehensive treatment of the application of geotechnical engineering to site selection, site exploration, design, operation and closure of mine waste storage facilities.The level and content are suitable as a technical source and reference for practising engineers engaged both in