Process Intensification for Carbon Capture and Utilization
Will be published approx. on 1. November 2026
Book
Paperback/Softback
500 pages
978-0-443-40457-3 (ISBN)
Description
Process Intensification for Carbon Capture and Utilization provides a comprehensive review of carbon dioxide capture and utilization (CCU) technologies from a process engineering approach, focusing on process intensification to enhance sustainability and efficient chemical process and process design. Sections provide a brief theoretical overview of CCU process design and then build to practical guidance - offering case studies and real-world applications for achieving environmental sustainability goals, reduction of carbon emissions, and the creation of value-added products from captured CO2. Chapters also highlight advancements in methodologies and tools of Process Systems Engineering (PSE) for the design of CCU processes, including outlines and worked examples.
This book is suitable for a wide audience in academia and industry interested in CCU technologies, and will be valuable for students, research scientists, engineers, and practitioners seeking an overview or in-depth knowledge on CCU. Additionally, the book's content can be used as teaching resources for advanced courses.
This book is suitable for a wide audience in academia and industry interested in CCU technologies, and will be valuable for students, research scientists, engineers, and practitioners seeking an overview or in-depth knowledge on CCU. Additionally, the book's content can be used as teaching resources for advanced courses.
More details
Language
English
Place of publication
Philadelphia
United States
Target group
Professional and scholarly
Product notice
Paperback (trade)
Unsewn / adhesive bound
Dimensions
Height: 235 mm
Width: 191 mm
Weight
449 gr
ISBN-13
978-0-443-40457-3 (9780443404573)
Copyright in bibliographic data is held by Nielsen Book Services Limited or its licensors: all rights reserved.
Schweitzer Classification
Persons
Dr. Suttichai Assabumrungrat is Full Professor of Chemical Engineering, Faculty of Engineering at Chulalongkorn University, Thailand. Dr. Assabumrungrat received his B.Eng. degree (1st class honor) in Chemical Engineering from Chulalongkorn University (Thailand), M.Sc. (Distinction) in Advanced in Chemical Engineering, and Ph.D. degree in Chemical Engineering from Imperial College, London (UK). His research interest includes multifunctional reactors, reactive distillation, and fuel cell. Metta Chareonpanich is a Professor of Chemical Engineering, Faculty of Engineering at Kasetsart University, Thailand. Dr. Chareonpanich received her B.Sc. degree in Chemistry from Kasetsart University, M.Eng. in Chemical Engineering from Chulalongkorn University, and D.Eng. degree in Applied Chemistry from Tohoku University. Her research applications primarily focus on multifunctional catalysts for green chemical feedstock and alternative energy production from greenhouse gases. Dr. Thongthai Witoon is a Full Professor in the Department of Chemical Engineering, Faculty of Engineering, Kasetsart University, Thailand. He
earned his B.Eng. (First Class Honors), M.Eng., and D.Eng. degrees in Chemical Engineering from Kasetsart University. His research focuses on
carbon capture and utilization, catalytic conversion of CO? to value-added chemicals, catalyst and adsorbent development, and
sustainable materials from waste resources. His work includes the design of catalytic and adsorptive materials for applications in CO? capture, methanol synthesis, the reverse water-gas shift reaction, and related clean energy processes.
earned his B.Eng. (First Class Honors), M.Eng., and D.Eng. degrees in Chemical Engineering from Kasetsart University. His research focuses on
carbon capture and utilization, catalytic conversion of CO? to value-added chemicals, catalyst and adsorbent development, and
sustainable materials from waste resources. His work includes the design of catalytic and adsorptive materials for applications in CO? capture, methanol synthesis, the reverse water-gas shift reaction, and related clean energy processes.
Content
Section 1: Overviews of Process Intensification for Sustainable Carbon Solutions
1. Overviews of Process Intensification and Its Applications for Sustainable Carbon Solutions
Section 2: Process Intensification for Carbon Capture and Case Studies
2. Overviews of Carbon Capture Technologies
3. Rotating Packed Bed with Absorption for Carbon Capture
4. KIER CO2 Capture Technology
5. Adsorption-Based Technologies for Carbon Capture
6. Material Design for Carbon Capture Technologies
7. Membrane-Based Technologies for Carbon Capture
8. Algal-Based Technologies for Carbon Capture
Section 3: Process Intensification for Carbon Utilization and Case Studies
9. Overviews of Carbon Utilization Technologies
10. Carbon Utilization Innovations: Integration of Process Intensification for Efficiency Enhancements in Carbon Capture and Utilization
11. Scalable Carbon Utilization Solutions
12. Utilization of CO2 for Enhanced Oil Recovery (EOR)
13. Utilization of CO2 for Production of Chemicals (Olefins and Small Alcohols)
14. CO2 Valorization via Electrochemical Capture and Conversion
15. Utilization of CO2 for Production of Fuels (Synthetic Methane/Methane Synthesis)
16. Bio-Conversion of CO2 into Biofuels and Other Value-Added Chemicals
Section 4: Process Creation, Design and Analysis for Process Intensification of CO2 Capture and Utilization and Case Studies
17. Overviews of Technologies for Integrated Carbon Capture and Utilization
18. Methods and Tools for Development of Process Intensified Process
19. Process Intensification Strategies for Carbon Capture Innovation
Section 5: Perspective, Challenges, and Future Direction
20. Perspective, Challenges, and Future Direction
1. Overviews of Process Intensification and Its Applications for Sustainable Carbon Solutions
Section 2: Process Intensification for Carbon Capture and Case Studies
2. Overviews of Carbon Capture Technologies
3. Rotating Packed Bed with Absorption for Carbon Capture
4. KIER CO2 Capture Technology
5. Adsorption-Based Technologies for Carbon Capture
6. Material Design for Carbon Capture Technologies
7. Membrane-Based Technologies for Carbon Capture
8. Algal-Based Technologies for Carbon Capture
Section 3: Process Intensification for Carbon Utilization and Case Studies
9. Overviews of Carbon Utilization Technologies
10. Carbon Utilization Innovations: Integration of Process Intensification for Efficiency Enhancements in Carbon Capture and Utilization
11. Scalable Carbon Utilization Solutions
12. Utilization of CO2 for Enhanced Oil Recovery (EOR)
13. Utilization of CO2 for Production of Chemicals (Olefins and Small Alcohols)
14. CO2 Valorization via Electrochemical Capture and Conversion
15. Utilization of CO2 for Production of Fuels (Synthetic Methane/Methane Synthesis)
16. Bio-Conversion of CO2 into Biofuels and Other Value-Added Chemicals
Section 4: Process Creation, Design and Analysis for Process Intensification of CO2 Capture and Utilization and Case Studies
17. Overviews of Technologies for Integrated Carbon Capture and Utilization
18. Methods and Tools for Development of Process Intensified Process
19. Process Intensification Strategies for Carbon Capture Innovation
Section 5: Perspective, Challenges, and Future Direction
20. Perspective, Challenges, and Future Direction