Carbon Capture and Environmental Sustainability

著者名：Sotoodeh, Karan

Wiley（2026/05/27発売）

• 言語：ENG
• ISBN：9781394436378
• eISBN：9781394436385

Description

An interdisciplinary guide to carbon capture across technology, policy, and economics

Of the approximately 36 billion tons of CO2 emitted annually, only about 40 million tons are currently captured and stored, highlighting a critical gap in global decarbonization efforts. Carbon Capture and Environmental Sustainability: Pathways to a Low-Carbon Future provides an integrated perspective on carbon capture technologies, climate science, carbon footprint analysis, and their integration with renewable energy systems and digitalization-driven energy optimization.

The book goes beyond technical fundamentals to examine the economic, policy, social, and cultural factors that influence the deployment and scalability of carbon capture solutions. It combines engineering-based analysis with accessible discussion of how these broader dimensions shape real-world energy transition pathways. Readers gain the tools to evaluate emerging carbon capture technologies and assess real-world sustainability of proposed climate solutions.

The book also covers:

• How digitalization and energy optimization strategies enhance the efficiency and scalability of carbon capture and storage operations
• Policy frameworks and regulatory mechanisms that drive or constrain adoption of carbon capture at national and international levels
• Social and cultural factors influencing public acceptance, community and stakeholder engagement with decarbonization projects across different regions
• Economic analysis of carbon capture deployment costs, funding models, and market incentives supporting low-carbon energy transitions
• Integration of carbon capture with renewable energy systems to enhance overall emissions reduction

Written for engineers, energy-sector professionals, researchers, graduate students, and sustainability practitioners, this book provides a practical, interdisciplinary foundation for understanding how carbon capture and sustainability strategies operate across technical, societal, and economic domains, enabling informed decision-making in decarbonization efforts.

Table of Contents

Preface xiii

1 Introduction to Carbon Capture and Environmental Sustainability 1

1.1 What is Carbon Capture? 1

1.2 The Role of CO₂ in Global Climate Change 3

1.3 Definitions and Pillars of Environmental Sustainability 3

1.4 Historical Context and Evolution of Carbon Capture Technologies 4

1.5 Why Carbon Capture is Needed: A Multidimensional Perspective 5

1.6 Bridging Policy, Environment, and Ethics 10

1.7 Structure and Objectives of This Book 13

1.8 Key Highlights (Chapter Summary) 14

References 14

2 Climate Change, Global Emissions, and the Need for Carbon Capture 17

2.1 Overview of Global Climate Target and Role of CCS 17

2.2 Sources and Trends of Greenhouse Gas Emissions 19

2.3 Role of CO₂ and Its Global Impact 22

2.4 The Scientific Basis: IPCC Reports and Climate Models 27

2.5 The Paris Agreement and Global Carbon Targets 28

2.6 Limits of Current Climate Action and the Need for Carbon Capture 29

2.7 Key Highlights (Chapter Summary) 32

References 33

3 Environmental Justice and Carbon Management Policies 37

3.1 What is Environmental Justice? 37

3.2 Historical Examples of Environmental Inequities 39

3.3 Justice in the Context of Carbon Capture 39

3.4 Policy Frameworks Supporting Just Carbon Management 41

3.5 Environmental Racism and Community Resistance 44

3.6 Ensuring Equitable Access and Participation 46

3.7 Key Highlights (Chapter Summary) 47

References 47

4 Principles and Types of Carbon Capture Technologies 51

4.1 Overview of Carbon Capture Mechanisms 51

4.2 Post- combustion Capture 52

4.3 Precombustion Capture 54

4.4 Oxy- Fuel Combustion 56

4.5 Direct Air Capture (DAC) 57

4.6 Bioenergy with Carbon Capture and Storage (BECCS) 59

4.7 Comparative Evaluation— Efficiency, Cost, and Feasibility 62

4.8 Key Highlights (Chapter Summary) 63

References 64

5 Social Acceptance and Public Perception of Carbon Capture Projects 67

5.1 Why Public Perception Matters? 67

5.2 Historical Cases of Public Opposition 68

5.3 Risk Communication and Transparency 69

5.4 Influence of Media and Social Networks 71

5.5 Behavioral Psychology and Climate Technology 73

5.6 Strategies for Building Trust and Acceptance 75

5.7 Key Highlights (Chapter Summary) 76

References 77

6 Health, Safety, and Environmental (HSE) Considerations 81

6.1 Overview of HSE in Carbon Capture Projects 81

6.2 Occupational and Community Health Concerns 81

6.3 Environmental Impacts and Risk Scenarios 85

6.4 Pipeline Safety and CO₂ Transportation Hazards 86

6.5 Safety Regulations and International Standards 89

6.6 Emergency Response and Contingency Planning 91

6.7 Key Highlights (Chapter Summary) 93

References 94

7 Carbon Capture and Sustainable Development Goals (SDGs) 99

7.1 Overview of the SDGs and Their Relevance to Carbon Capture 99

7.2 SDG 13 (Climate Action) 101

7.3 SDG 7 (Clean Energy) and Renewable Integration 103

7.4 SDG 9 (Industry, Innovation, and Infrastructure) 103

7.5 SDG 11 (Sustainable Cities and Communities) 106

7.6 Balancing Benefits and Challenges of CCS and SDGs 110

7.7 Key Highlights (Chapter Summary) 110

References 111

8 Carbon Capture in Developing vs. Developed Countries 115

8.1 Global Inequality in CCS Technology Access 115

8.2 Infrastructure Gaps in Developing Countries 118

8.3 Financial Barriers and the Role of Climate Finance 120

8.4 Policy Readiness and Institutional Capacity 123

8.5 North– South Technology Transfer and Equity 125

8.6 Case Studies: Contrasting Regional Approaches Toward CCS 127

8.7 Conclusion 130

8.8 Key Highlights (Chapter Summary) 131

References 131

9 Policy Mechanisms and Regulatory Frameworks 137

9.1 Overview of Carbon Policy Mechanisms 137

9.2 Carbon Pricing: Taxes and Emissions Trading Systems 139

9.3 Regulatory Mandates and Technology Standards 140

9.4 Government Subsidies and Incentives 142

9.5 International Frameworks and Agreements 144

9.6 Evaluating Policy Effectiveness and Gaps 147

9.7 Key Highlights (Chapter Summary) 149

References 150

10 Community Engagement and Ethical Dimensions of Carbon Projects 155

10.1 Ethics of Large- Scale Environmental Technologies 155

10.2 Procedural Justice and Inclusive Governance 157

10.3 Informed Consent and Community Rights 159

10.4 Trust- Building and Long- Term Commitments 161

10.5 Benefit- Sharing Mechanisms 163

10.6 Avoiding Green Colonialism and Ethical Missteps 165

10.7 Key Highlights (Chapter Summary) 167

References 167

11 Carbon Capture and the Water–Energy Nexus 171

11.1 Understanding the Water–Energy Nexus 171

11.2 Water Demands of Carbon Capture Processes 172

11.3 Energy Requirements and Carbon Intensity 174

11.4 Geographic and Regional Constraints 177

11.5 Design Strategies for Resource Optimization 180

11.6 Challenges Facing CCS Projects 182

11.7 Key Highlights (Chapter Summary) 183

References 184

12 Integration of Carbon Capture with Renewable Energy Systems 189

12.1 Why Integration with Renewables Matters 189

12.2 Opportunities for Bioenergy with CCS (BECCS) 191

12.3 Solar- and Wind- Powered Capture Systems 193

12.4 Hybrid Plant Designs and Case Examples 197

12.5 Energy Storage, Load Management, and Flexibility 199

12.6 Technical and Policy Challenges of Integration 204

12.7 Key Highlights (Chapter Summary) 205

References 206

13 Carbon Capture, Circular Economy, and Resource Efficiency 211

13.1 Circular Economy Structure 211

13.2 From Waste to Value: CO₂ as a Resource 213

13.3 Utilization Pathways: Fuels, Chemicals, and Building Materials 216

13.4 Resource Efficiency in Capture Technologies 220

13.5 Designing Closed- Loop Carbon Systems 222

13.6 Industrial Symbiosis and Innovation 223

13.7 Key Global CCS Initiatives and Projects 225

References 225

14 Economic Considerations and Financial Models 231

14.1 Overview of Global Climate Targets and the Role of CCS 231

14.2 Levelized Cost of CO₂ Abatement (LCCA) 233

14.3 Risk and Return in Low- Carbon Investment 240

14.4 Carbon Credit Trading and Market Incentives 244

14.5 Public–Private Partnerships and Financing Mechanisms 246

14.6 Case Studies of Financially Feasible Projects 249

14.7 Key Highlights (Chapter Summary) 251

References 252

15 Case Studies in Carbon Capture and Environmental Impact 257

15.1 Case Study 1: Large-Scale CCS in the Power Sector 257

15.2 Case Study 2: Industrial Capture and CO₂ Utilization 260

15.3 Case Study 3: BECCS Pilot Projects 263

15.4 Case Study 4: Community- Led Environmental Monitoring 266

15.5 Comparative Analysis of Environmental Outcomes 269

15.6 Key Takeaways and Lessons Learned 270

15.7 Key Highlights (Chapter Summary) 272

References 273

16 Future Perspectives: Justice, Sustainability, and System Redesign 277

16.1 Summary of Crosscutting Themes 277

16.2 Rethinking Carbon Capture Beyond Technology 279

16.3 Long- Term Justice and Global Equity 282

16.4 Regenerative Environmental Governance 285

16.5 Innovations on the Horizon 287

16.6 Strategic Recommendations and Calls to Action 292

16.7 Key Highlights (Chapter Summary) 293

References 294

17 Artificial Intelligence, Digitalization, and Smart Carbon Capture Systems 299

17.1 Role of Digitalization in Carbon Capture 299

17.2 Foundations of AI and Machine Learning in Carbon Capture and Storage 302

17.3 Digital Twins for Process Optimization 306

17.4 Predictive Maintenance and Leak Detection Systems 310

17.5 Automation and Smart Safety Systems 313

17.6 Ethical, Workforce, and Cybersecurity Considerations 316

17.7 Key Highlights (Chapter Summary) 318

References 319

18 Nature- Based Carbon Capture and Ecological Solutions 325

18.1 Introduction to Nature- Based Carbon Removal 325

18.2 Forest- Based Carbon Capture Systems 328

18.3 Wetlands, Mangroves, and Blue Carbon Ecosystems 331

18.4 Ocean Alkalinity and Marine- Based Approaches 333

18.5 Soil- Carbon Sequestration in Agriculture 335

18.6 Synergy Between Nature- Based and Engineered CCS Solutions 337

18.7 Key Highlights (Chapter Summary) 340

References 341

19 Education, Skills Development, and Public Capacity- Building for Carbon Capture 345

19.1 Importance of Knowledge and Skills in CCS Expansion 345

19.2 University Programs and Technical Training Pathways 347

19.3 Interdisciplinary Competencies for Future Workforce 349

19.4 Public Awareness and Climate Education Programs 352

19.5 International Collaboration and Knowledge Transfer 354

19.6 Strategies for Long- Term Capacity- Building 356

19.7 Key Highlights (Chapter Summary) 358

References 358

20 Ethics, Governance, and Long- Term Stewardship of Carbon Storage 363

20.1 Ethical Considerations in Long- Term Carbon Storage 363

20.2 Governance Models and Institutional Responsibilities 365

20.3 Long- Term Monitoring and Liability Frameworks 368

20.4 Transparency and Community Accountability 371

20.5 International Legal and Regulatory Perspectives 373

20.6 Designing Durable Stewardship Frameworks 374

20.7 Key Highlights (Chapter Summary) 376

References 377

Index 383