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Advances and Technology Development in Greenhouse Gases: Emission, Capture and Conversion
Carbon Capture Technologies
- 1st Edition - July 20, 2024
- Editors: Mohammad Reza Rahimpour, Mohammad Amin Makarem, Maryam Meshksar
- Language: English
- eBook ISBN:9 7 8 - 0 - 4 4 3 - 1 9 2 3 4 - 0
Advances and Technology Development in Greenhouse Gases: Emission, Capture and Conversion is a comprehensive series that discusses the composition and properties of greenhous… Read more
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Request a sales quoteAdvances and Technology Development in Greenhouse Gases: Emission, Capture and Conversion is a comprehensive series that discusses the composition and properties of greenhouse gases (GHGs) and introduces different sources of GHGs’ emission and the relation between GHGs and global warming. The comprehensive and detailed presentation of common technologies as well as novel research related to all aspects of GHGs makes this work an indispensable encyclopedic resource for researchers in academia and industry.
Carbon Capture Technologies is devoted to efficient technologies utilized for separating carbon-made GHGs. Section 1 reviews carbon capture concepts followed by a meticulous investigation of different classes of capture methods. Section 2 surveys the absorption process, including amines, physical absorbents, ionic liquids, and deep eutectic and nanoparticle-enhanced solvents. Section 3 addresses adsorption-based strategies with a focus on the role of different solid adsorbents. Section 4 introduces technologies that benefit from membranes and considers different materials utilized in the fabrication of membranes. Finally, Section 5 deals with other as state-of-the-art alternatives in carbon capture.
- Introduces carbon capture concepts and challenges
- Describes various absorption and adsorption processes for carbon capture
- Includes various membrane technologies for carbon capture
Researchers in academia, students and professors in chemical engineering, oil and gas engineering, and mechanical engineering Refinery and petrochemical engineers, Energy producers and utilities, Power generation plants, Extractive companies, Process design companies, Oil, gas and petrochemical industries
- Cover image
- Title page
- Table of Contents
- Copyright
- List of contributors
- About the editors
- Preface
- Reviewer acknowledgments
- Section 1: Carbon capture concepts
- Chapter one. Introduction to carbon capture methods and technologies
- Abstract
- 1.1 Introduction
- 1.2 Present scenario
- 1.3 Part played by carbon capture and storage
- 1.4 Pathways to capture CO2 postcombustion
- 1.5 Future generation technologies to capture CO2
- 1.6 Negative emission technologies
- 1.7 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Section 2: Absorption techniques for carbon capture
- Chapter two. Application of amines for carbon capture
- Abstract
- 2.1 Introduction
- 2.2 Amine-based carbon capture processes
- 2.3 Amine-functionalized solid
- 2.4 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter three. Physical and hybrid solvents for carbon capture: ethers, ammonia, and methanol
- Abstract
- 3.1 Introduction
- 3.2 Carbon capture techniques
- 3.3 Physical sorption techniques
- 3.4 Commercial physical absorption process
- 3.5 Techno-economic analysis of physical absorption
- 3.6 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter four. Ionic liquids and deep eutectic solvents for carbon capture
- Abstract
- 4.1 Introduction
- 4.2 Principles and procedures
- 4.3 Processes
- 4.4 Current applications and cases
- 4.5 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter five. Carbon capture by solvents modified with nanoparticle
- Abstract
- 5.1 Introduction
- 5.2 Nanoparticles in carbon capture
- 5.3 Mechanisms of nanoparticle-enhanced carbon capture
- 5.4 Methods for nanoparticle synthesis
- 5.5 Characterization techniques for nanoparticles
- 5.6 Surface modification of nanoparticles for carbon capture
- 5.7 Economic and environmental considerations
- 5.8 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter six. Carbon capture by encapsulated liquid sorbents
- Abstract
- 6.1 Introduction
- 6.2 Different methods for carbon capture
- 6.3 Encapsulated liquid sorbents used for carbon capture
- 6.4 Sorbent selection criteria
- 6.5 Carbon capture with encapsulated ionic liquids
- 6.6 Carbon capture by amine-based sorbents
- 6.7 Performance and efficiency of encapsulated sorbents
- 6.8 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter seven. Novel gas–liquid contactors for carbon capture: mini- and microchannels and rotating packed beds
- Abstract
- 7.1 Introduction
- 7.2 Mini- and microchannels for CO2 capture
- 7.3 Rotating packed bed for CO2 absorption
- 7.4 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter eight. Cryogenic fractionation for carbon capture
- Abstract
- 8.1 Introduction
- 8.2 Carbon capture and sequestration
- 8.3 CO2 capture technologies
- 8.4 Cryogenic CO2 capture technologies
- 8.5 Conclusion and future outlooks
- Abbreviations
- References
- Chapter nine. Enzymatic carbon capture and conversion technology
- Abstract
- 9.1 Introduction
- 9.2 Enzymatic reactions for carbon capture
- 9.3 Enzyme immobilization
- 9.4 Biocatalytic absorption column for carbon capture
- 9.5 Biocatalytic membranes for carbon capture
- 9.6 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter ten. Economic assessments and environmental challenges of carbon capture using absorption techniques
- Abstract
- 10.1 Introduction
- 10.2 Principles and procedures of CO2 capture technologies
- 10.3 Processes
- 10.4 Current applications
- 10.5 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Section 3: Adsorption techniques for carbon capture
- Chapter eleven. Swing technologies for carbon capture: pressure, thermal, vacuum, electrical, and mixed swing processes
- Abstract
- 11.1 Introduction
- 11.2 Cycles
- 11.3 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter twelve. Carbon capture by carbonaceous sorbents
- Abstract
- 12.1 Introduction
- 12.2 Principles and procedures
- 12.3 Processes
- 12.4 Current applications and cases
- 12.5 Application of graphene-based adsorbents for CO2 adsorption
- 12.6 Conclusion and future outlooks
- Acknowledgments
- Author contribution statement
- Abbreviations and symbols
- References
- Chapter thirteen. Metal oxides and porous-based sorbents for carbon capture: metal-organic frameworks, porous silica, zeolites
- Abstract
- 13.1 Introduction
- 13.2 Carbon dioxide capture methods
- 13.3 Carbon dioxide adsorption processes
- 13.4 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter fourteen. Carbon dioxide adsorption over photocatalyst
- Abstract
- 14.1 Introduction
- 14.2 Photocatalysis
- 14.3 Carbon dioxide adsorption
- 14.4 Photocatalytic carbon dioxide conversion
- 14.5 Applications
- 14.6 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter Fifteen. Amino-based adsorbents for carbon capture
- Abstract
- 15.1 Introduction
- 15.2 Polyamine-based materials with high carbon dioxide adsorption capacity
- 15.3 Development of polyamine carbon dioxide adsorbents
- 15.4 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter sixteen. Carbon dioxide capture using algae
- Abstract
- 16.1 Introduction
- 16.2 Mechanism
- 16.3 Closed system bioreactor
- 16.4 Open system
- 16.5 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Section 4: Membrane technology for carbon capture
- Chapter seventeen. Hollow-fiber membranes for carbon capture and separation
- Abstract
- 17.1 Introduction
- 17.2 Membrane module design
- 17.3 Principles and performance
- 17.4 Issues related to hollow-fiber mixed-matrix membranes fabrication for CO2 removal from CH4 and N2
- 17.5 Current applications and cases
- 17.6 Conclusion and future outlooks
- Abbreviations
- References
- Chapter eighteen. Carbon capture and separation by polymeric membranes
- Abstract
- 18.1 Introduction
- 18.2 Theory
- 18.3 Membrane architecture
- 18.4 Polymers
- 18.5 Robeson’s upper bound
- 18.6 Facilitated transport membranes
- 18.7 Current applications
- 18.8 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter nineteen. Carbon capture and separation by ionic liquid membranes
- Abstract
- 19.1 Introduction
- 19.2 Types of ionic liquid membranes
- 19.3 Alternative to selective membranes: membrane contactors
- 19.4 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter twenty. Metal-organic framework mixed matrix membranes for carbon capture and separation
- Abstract
- 20.1 Introduction
- 20.2 Metal-organic framework synthesis and characterization
- 20.3 Mixed matrix membrane preparation and characterization
- 20.4 Performance of metal-organic framework mixed matrix membranes for carbon capture and separation
- 20.5 Applications of metal-organic framework mixed matrix membranes in carbon capture and separation
- 20.6 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Section 5: Other technologies for carbon capture
- Chapter twenty-one. Oxyfuel combustion as a carbon capture technique
- Abstract
- 21.1 Introduction
- 21.2 Climate change: necessity and exigency for clean combustion technologies
- 21.3 Carbon capture and storage with the power generation
- 21.4 Comparing with postcombustion-capturing technique
- 21.5 Oxypower cycle design characteristics and consideration
- 21.6 Oxycombustion characteristics and final remarks
- 21.7 Current demonstration plants, proof-of-concepts, and pilot test rigs
- 21.8 Iran CO2 emission and outlook of oxyfuel combustion for carbon capture and storage in Iran
- 21.9 Conclusion and future outlooks
- Abbreviations and symbols
- References
- Chapter twenty-two. Recent advances and new concepts of carbon capture
- Abstract
- 22.1 Introduction
- 22.2 Technologies and methods
- 22.3 Challenges in carbon-capture technologies
- 22.4 Active projects in carbon capturing
- 22.5 Concepts in carbon capture
- 22.6 Adsorption-based carbon capture
- 22.7 Chemical fixation of CO2
- 22.8 Conclusion and future outlooks
- Acknowledgments
- Abbreviations and symbols
- References
- Chapter twenty-three. Economic assessment and environmental challenges of carbon capture using membrane techniques
- Abstract
- 23.1 Introduction
- 23.2 Principles and procedures
- 23.3 Processes
- 23.4 Current applications and cases
- 23.5 Conclusion and future outlooks
- Abbreviations and symbols
- Subscripts and superscripts
- References
- Index
- No. of pages: 960
- Language: English
- Edition: 1
- Published: July 20, 2024
- Imprint: Elsevier
- eBook ISBN: 9780443192340
MR
Mohammad Reza Rahimpour
Prof. Mohammad Reza Rahimpour is a professor in Chemical Engineering at Shiraz University, Iran. He received his Ph.D. in Chemical Engineering from Shiraz University joint with University of Sydney, Australia 1988. He started his independent career as Assistant Professor in September 1998 at Shiraz University. Prof. M.R. Rahimpour, was a Research Associate at University of California, Davis from 2012 till 2017. During his stay in University of California, he developed different reaction networks and catalytic processes such as thermal and plasma reactors for upgrading of lignin bio-oil to biofuel with collaboration of UCDAVIS. He has been a Chair of Department of Chemical Engineering at Shiraz University from 2005 till 2009 and from 2015 till 2020. Prof. M.R. Rahimpour leads a research group in fuel processing technology focused on the catalytic conversion of fossil fuels such as natural gas, and renewable fuels such as bio-oils derived from lignin to valuable energy sources. He provides young distinguished scholars with perfect educational opportunities in both experimental methods and theoretical tools in developing countries to investigate in-depth research in the various field of chemical engineering including carbon capture, chemical looping, membrane separation, storage and utilization technologies, novel technologies for natural gas conversion and improving the energy efficiency in the production and use of natural gas industries.
Affiliations and expertise
Professor, Department of Chemical Engineering, Shiraz University, Shiraz, IranMM
Mohammad Amin Makarem
Dr. Mohammad Amin Makarem is a research associate at Shiraz University. His research interests are gas separation and purification, nanofluids, microfluidics, catalyst synthesis, reactor design, and green energy. In gas separation, his focus is on experimental and theoretical investigation and optimization of
pressure swing adsorption process, and in the gas purification field, he is working on novel technologies such as microchannels. Recently, he has investigated methods of synthesizing biotemplate nanomaterials and catalysts. Besides, he has collaborated in writing and editing various books and book chapters for famous publishers such as Elsevier, Springer, and Wiley.
Affiliations and expertise
Research Associate, Department of Chemical Engineering, Shiraz University, Shiraz, IranMM
Maryam Meshksar
Maryam Meshksar is a research associate at Shiraz University. Her research has focused on gas separation, clean energy, and catalyst synthesis. In gas separation, she is working on membrane separation process, and in the clean energy field, she has worked on different reforming-based processes for syngas production from methane experimentally. She has also synthesized novel catalysts for these processes which are tested in for the first time. Besides, she has reviewed novel technologies like microchannels for energy production. Recently, she has written various book-chapters for famous publishers such as Elsevier, Springer, and Wiley.
Affiliations and expertise
Research Associate, Department of Chemical Engineering, Shiraz University, Shiraz, IranRead Advances and Technology Development in Greenhouse Gases: Emission, Capture and Conversion on ScienceDirect