Carbon Capture and Storage in the Oil and Gas Industry : Solutions for the Energy Transition / Edited by Birol Dindoruk, Department of Petroleum Engineering, Texas A&M University, Houston, TX, United States, Cenk Temizel, Saudi Aramco, Dhahran, Saudi Arabia, Ram Ratnakar, Department of Chemical Biomolecular Engineering, Cullen College of Engineering, University of Houston, Houston, TX, United States.

Format:

Book

Contributor:

Dindoruk, Birol, editor.

Temizel, Cenk, editor.

Ratnakar, Ram R., editor.

Language:

English

Subjects (All):

Carbon sequestration.

Gas industry--Environmental aspects.

Gas industry.

Oil industries--Environmental aspects.

Oil industries.

Petroleum industry and trade--Environmental aspects.

Petroleum industry and trade.

Physical Description:

1 online resource (632 pages) : illustrations (chiefly color).

Other Title:

Solutions for the Energy Transition

Place of Publication:

Amsterdam ; London : Elsevier Science & Technology, [2026]

Summary:

Carbon Capture and Storage in the Oil and Gas Industry: Solutions for the Energy Transition introduces engineers to the basics in CCUS and how oil and gas can support activity. Containing both academic and corporate contributors, topics include screening selection, best practices, and the latest advances. Field applications and available case studies are included to help users learn and apply concepts to real-world applications. Led by three experienced oil and gas experts, this book will define and guide the oil and gas engineer into a must-have skill in energy transition that will help them contribute to net zero goals.

Contents:

Front Cover

CARBON CAPTURE AND STORAGE IN THE OIL AND GAS INDUSTRY

CARBON CAPTURE AND STORAGE IN THE OIL AND GAS INDUSTRY:Solutions for the Energy Transition

Copyright

Dedication

Contetns

Contributors

Preface

Acknowledgments

1 - Carbon capture and storage in the oil and gas industry: Introduction

1.1 The oil and gas industry

1.2 The energy transition

1.3 The role of carbon capture and storage for a sustainable energy sector

1.4 Nomenclature

References

2 - Fundamental concepts on carbon capture and storage

2.1 CO2 emissions and sources

2.2 CO2 capture and separation technologies

2.2.1 Direct air capture

2.2.2 Pre-combustion carbon capture

2.2.3 Post-combustion carbon capture

2.2.4 Oxy-fuel combustion capture

2.2.5 Absorption capture systems

2.2.6 Adsorption capture systems

2.2.7 Membrane separation systems

2.2.8 Cryogenic separation systems

2.3 CO2 storage technologies

2.3.1 Underground geological storage

2.3.1.1 Trapping mechanisms and storage security

2.3.1.1.1 Structural and stratigraphic trapping

2.3.1.1.2 Residual trapping

2.3.1.1.3 Solubility trapping

2.3.1.1.4 Mineral trapping

2.3.1.2 Type of the potential geological sinks

2.3.1.2.1 Depleted oil and gas reservoirs

2.3.1.2.2 Enhanced oil recovery

2.3.1.2.3 Deep saline aquifers

2.3.1.2.4 Un-mineable coal seams

2.3.1.2.5 Basalt formations

2.3.2 Ocean storage

2.3.3 Terrestrial ecosystem storage

2.4 Summary

3 . Screening and selection of carbon capture and storage technologies

3.1 Introduction

3.2 Screening and selection of liquid absorbents

3.2.1 Introduction and overview

3.2.2 Physical absorbents

3.2.3 Chemical absorbents

3.2.4 Screening and selection criteria for liquid absorbents.

3.2.5 Methods for the screening and selection of liquid absorbents

Experimental measurements

Process and equilibrium models

Predictive models

Computer-aided molecular design (CAMD) models

3.3 Screening and selection of solid adsorbents

3.3.1 Introduction and overview

3.3.2 Important characteristics of solid adsorbents

3.3.3 Overview of different adsorbent types

3.3.4 Performance metrics for the screening of solid adsorbents

3.3.5 Methods for the screening of solid adsorbents - multiscale screening approaches

3.3.5.1 Porous material databases and structural characterization tools

3.3.5.2 Molecular simulation

3.3.5.2.1 Grand canonical Monte Carlo simulation

3.3.5.2.2 Molecular dynamics simulation

3.3.5.3 Process simulation and optimization

Column properties

Pellet properties

Properties of adsorbent material crystals

Feed properties

Equilibrium adsorption data

3.4 Screening and selection of membrane materials

3.4.1 Introduction and overview

3.4.2 Membrane separation mechanisms and evaluation parameters

3.4.3 Membrane screening and selection in different carbon capture scenarios

3.4.3.1 Precombustion capture by membranes

3.4.3.1.1 H2-selective membranes

Metallic membranes

Porous inorganic membranes

Polymer-based and mixed-matrix membranes

3.4.3.1.2 CO2-selective membranes

3.4.3.2 Postcombustion capture by membranes

Polymeric membranes

Mixed-matrix membranes

3.4.3.3 Oxyfuel combustion capture by membranes

3.4.3.4 Direct air capture by membranes

3.4.4 Membrane selection criteria

3.5 Screening and selection of carbon storage

3.5.1 Introduction and overview

3.5.2 Important reservoir characteristics for CO2 storage screening

3.5.2.1 Storage capacity

3.5.2.2 Injectivity

3.5.2.3 Trapping mechanisms.

3.5.2.4 Containment

3.5.2.5 Cost

3.5.3 Screening and selection criteria of storage sites

3.6 Conclusion

4 - Carbon capture and storage types, applications, principles, and best practices in the world

4.1 Introduction

4.2 Fundamental trapping concepts on methods in oil and gas industry

4.2.1 CO2 stored by CO2-Enhanced oil recovery (CO2-EOR)

4.2.2 Saline water storage

4.2.3 Depleted reservoir storage

4.3 Theories

4.3.1 CO2-EOR

4.3.2 CO2 storage in saline water

4.3.3 CO2 storage in depleted reservoir

4.4 Case studies and applications

4.4.1 CO2-EOR case: SACROC

4.4.2 Carbon saline water storage in the Illinois Basin

4.4.3 Storage in depleted reservoirs

4.5 Summary

Further reading

5 - Carbon capture and storage in the oil and gas industry: Overview

5.1 Geological CO2 storage complex (site-characterization) (CG)

5.2 Surface and subsurface facilities

5.3 Primary CO2 storage reservoir target and seal(s)

5.3.1 Primary reservoir(s)

5.3.2 Seal(s)

5.3.3 Spill point and reservoir boundaries

5.4 Secondary containment (Secondary reservoir(s) and seal(s))

5.5 The workflow of CO2 storage complex characterization

5.5.1 Data collection

5.5.2 3D static geological model (I still need to modify this part)

5.5.3 CO storage site dynamic reservoir simulation

5.5.3.1 Coupled geomechanical and flow modeling

5.5.3.2 Reactive transport modeling

5.5.3.3 Reservoir dynamic/numeric simulation to predict plume dynamics

5.5.3.4 Numerical simulation to predict plume dynamics

5.5.3.5 Full field-scale coupled hydraulic, mechanical, and chemical simulation studies

5.6 Simulation of site-specific injection and monitoring strategy

5.7 Trapping Mechanisms

5.7.1 Physical trapping

5.7.2 Geochemical trapping.

5.8 Relevant rock properties and rock-fluid interactions during CO2 storage processes (CG)

5.9 Reservoir rock properties

5.9.1 Porosity

5.9.2 Pore size and grain size distribution and tortuosity

5.9.3 Surface area and specific surface area

5.9.4 Saturation

5.10 Fluid flow in porous medium

5.10.1 Permeability

5.11 Multi-phase flow (wettability, capillary pressure and relative permeability)

5.11.1 Wettability

5.11.2 Capillary pressure

5.11.3 Relative permeability

6 - Artificial intelligence and IR 4.0 applications in carbon capture and storage

6.1 Introduction

6.2 Fundamental concepts of AI and IR 4.0 applications

6.2.1 Machine learning and predictive analytics

6.2.2 Artificial neural networks

6.2.3 Big data analytics

6.2.4 Internet of Things

6.2.5 High-performance computing

6.2.6 Digital twin technology

6.2.7 Blockchain for data integrity and security

6.2.8 Robotics and automation

6.2.9 Enhanced oil recovery

6.2.10 Supply chain optimization

6.2.11 Supervisory Control and Data Acquisition systems

6.2.12 Advanced materials and chemical process optimization

6.2.13 Genetic algorithms for system design and optimization

6.2.14 Cybersecurity

6.3 Theories

6.4 Methods

6.5 Case studies/applications

6.6 Summary

6.7 Nomenclature

7 - Applications toward decarbonization, net zero, and energy transition efforts

7.1 Introduction

7.2 Fundamental concepts on decarbonization

7.3 Theories and methods for decarbonization in CCS strategies

7.4 Case Studies/Applications

7.5 Summary and conclusions

8 - Environmental and economic aspects of carbon capture and storage

8.1 Introduction

8.2 Fundamentals of environment and economics

8.2.1 Cost assessment of CCS.

8.2.1.1 Compositional analysis of fixed costs and variable costs

8.2.2 Benefits of CCS

8.2.2.1 Benefits arising from the application of CCS technologies in both private and public sectors

8.2.3 Ecological assessment using life cycle assessment

8.2.4 Environmental implications of conventional capture technologies

8.2.4.1 Systematic comparative analysis of the selected studies

8.2.4.2 Technology-driven differentiation

8.2.4.3 Capture techniques

8.2.4.4 CO2 transport and storage

8.2.5 Differentiation driven by LCA methodology

8.2.5.1 Functional unit

8.2.5.2 Time horizon

8.2.5.3 Spatial representation

8.3 Environmental issues and protection measures related to CCS

8.3.1 Environmental issues in capture systems

8.3.1.1 Environmental issues

8.3.1.2 Protection measures

8.3.2 Environmental issues in transportation systems

8.3.2.1 Environmental problems

8.3.2.2 Protection measures

8.3.2.3 Environmental assessment system

8.3.3 Environmental issues in storage systems

8.3.3.1 Introduction

8.3.3.2 Geological leakage problems

8.3.3.3 Engineering leakage problems

8.3.3.4 Protection technologies for CO2 leakage

8.4 Economic analysis of the entire CCS chain

8.4.1 Cost evaluation of the carbon capture process

8.4.2 Cost evaluation of the transportation process

8.4.3 Cost evaluation of the storage process

8.4.4 Revenue estimation of the entire CCS project

8.4.4.1 Economically optimal scale of CCS capacity

8.5 Case studies/applications

8.5.1 CO2 capture case: Boundary Dam project

8.5.1.1 Introduction

8.5.1.1.1 Location

8.5.1.1.2 Project details

8.5.1.1.3 Construction cost of the project

8.5.1.2 Operational performance of CO2 capture project

8.5.1.3 Measurements for protecting the environment

8.5.2 CO2 storage case: Weyburn project.

8.5.2.1 Introduction.

Notes:

Includes bibliographical references.

Description based on publisher supplied metadata and other sources.

ISBN:

9780443157622

0-443-15762-6

OCLC:

1564840014