Homogeneous Isomerization, Amination and Silicon Compounds Reactions
- 1st Edition - November 20, 2024
- Editors: Mohammad Reza Rahimpour, Mohammad Amin Makarem, Tayebeh Roostaie, Maryam Meshksar
- Language: English
- Paperback ISBN:9 7 8 - 0 - 4 4 3 - 1 5 7 1 2 - 7
- eBook ISBN:9 7 8 - 0 - 4 4 3 - 1 5 7 1 3 - 4
Homogeneous Isomerization, Amination and Silicon Compounds Reactions, a volume in the Advances in Homogeneous Catalysis series, is separated into three parts to provide comprehe… Read more
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Request a sales quoteHomogeneous Isomerization, Amination and Silicon Compounds Reactions, a volume in the Advances in Homogeneous Catalysis series, is separated into three parts to provide comprehensive coverage of isomerization, amination, and silicon compounds reactions with homogeneous catalysts. The first part presents isomerization of functionalized and non-functionalized alkenes. Homogeneous amination and hydroamination reactions are investigated in the second, while the final part covers homogeneous reactions of silicon compounds. The comprehensive coverage of the subject means this volume will be particularly useful to help bridge the gap between chemists and engineer’s knowledge and use of homogeneous catalysis.
- Includes fundamentals, reactor design, and process description of isomerization, amination, and silicon compounds homogeneous reactions
- Describes various isomerization, amination, and silicon compounds homogeneous reactions
- Explains isomerization, amination, and silicon compounds reactions economic and environmental challenges
Researchers, students and industry professionals, chemical engineers, refinery, chemical and petrochemistry chemists and engineers, process engineers, oil and gas engineers
- Title of Book
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- About the editors
- Preface
- Reviewer acknowledgments
- Part I. Homogeneous isomerization reactions
- Chapter 1. Overview of homogeneous isomerization catalytic systems
- 1 Introduction
- 2 Principles and procedures
- 3 Processes
- 4 Current application and cases
- 4.1 Homogeneous catalytic isomerization of glucose to fructose
- 4.2 Homogeneous catalytic isomerization of allylic alcohol
- 4.3 Homogeneous catalytic isomerization of alkene
- 4.4 Homogeneous isomerization-hydroformylation
- 5 Conclusion and future outlooks
- Abbreviations and symbols
- Chapter 2. Homogeneous isomerization of alkenes
- 1 Introduction
- 1.1 Isomerization of olefins with the homogeneous metal catalyst
- 2 Catalyst and deuterium oxide for homogeneous isomerization of alkenes
- 3 Natural and synthetic terpenic compounds for homogeneous isomerization of alkenes
- 4 Conclusion and future outlooks
- Abbreviations and symbols
- Part II. Homogeneous amination and hydroamination
- Chapter 3. Introduction to homogeneous amination and hydroamination
- 1 Introduction
- 2 Homogeneous and heterogeneous reactions
- 3 Chirality and stereoselectivity
- 4 Amination
- 5 Reductive amination
- 6 Borrowing hydrogen amination or hydrogen auto-transfer amination
- 7 Enzymatic and biocatalytic amination
- 8 Synthesis of alkaloids with amination methods
- 9 Conclusion and future outlooks
- Abbreviations and symbols
- Chapter 4. Hydroamination of alkenes using homogeneous catalysts
- 1 Introduction
- 1.1 Hydroamination of ethylene with homogeneous catalysts
- 2 Homogeneous metal catalysts in hydroamination
- 2.1 Transition metal catalysts of hydroamination of alkenes with homogeneous catalysts
- 2.2 Rare-earth metal complexes of hydroamination of alkenes with homogeneous catalysts
- 2.3 Gold-catalyzed hydroamination of alkenes with homogeneous catalysts
- 2.4 Silver-catalyzed hydroamination of alkenes with homogeneous catalysts
- 3 Conclusion and future outlooks
- Abbreviations and symbols
- Chapter 5. Homogeneous reductive amination and hydroaminomethylation
- 1 Introduction
- 2 Homogeneous reductive amination
- 2.1 Mo-catalyzed homogeneous reductive amination
- 2.2 Mn-catalyzed homogeneous reductive amination
- 2.3 Fe-catalyzed homogeneous reductive amination
- 2.4 Co-catalyzed homogeneous reductive amination
- 2.5 Ir-catalyzed homogeneous reductive amination
- 2.6 Rh-catalyzed homogeneous reductive amination
- 2.7 Ru-catalyzed homogeneous reductive amination
- 3 Homogeneous hydroaminomethylation
- 3.1 Rh-catalyzed hydroaminomethylation
- 3.2 Ru-catalyzed hydroaminomethylation
- 3.3 Ir-catalyzed hydroaminomethylation
- 3.4 Co-catalyzed hydroaminomethylation
- 4 Conclusion and future outlooks
- Abbreviations and symbols
- Chapter 6. Homogenous amination in bio-based chemistry
- 1 Introduction
- 2 Hydrogen borrowing catalysis for the amination of bio-based alcohols
- 3 Furfural transformation into high-quality chemicals and sustainable solvents
- 4 Reactivity of hydroxymethylfurfural
- 5 Epoxy resins
- 6 Lignin-based polyurethanes
- 7 Amination
- 8 Conceptual biorefinery platform: Glycolaldehyde as a bio-based C2 platform molecule
- 9 Acetals
- 10 Nitrogen-containing derivatives
- 11 Triazoles
- 12 Glycosides
- 13 Conclusion and future outlooks
- Abbreviations and symbols
- Chapter 7. Environmental impacts and economic assessment of homogeneous amination processes
- 1 Introduction
- 2 Environmental impact of homogeneous amination
- 2.1 Toxicity of amines
- 2.2 Toxicity of solvents
- 2.3 Toxicity of catalysts
- 3 Analysis of different types of catalysts and reactions
- 3.1 Catalysis by ammonium ion
- 3.2 Catalysis by amide ion
- 3.3 Catalysis by organolanthanides
- 3.4 Catalysis by enzymes
- 3.5 Photocatalysis
- 3.6 Catalysis by metals
- 3.6.1 Cobalt catalyst
- 3.6.2 Palladium catalysts
- 3.6.3 Ruthenium catalysts
- 3.6.4 Rhodium catalysts
- 3.6.5 Molybdenum catalyst
- 3.6.6 Manganese catalyst
- 3.6.7 Iron catalyst
- 3.6.8 Iridium catalyst
- 3.6.9 Copper catalyst
- 3.6.10 Nickel catalyst
- 4 Conclusion and future outlooks
- Abbreviations and symbols
- Chapter 8. Homogenous amination in polymer chemistry
- 1 Introduction
- 2 Homogeneous amination
- 3 Synthesis and fabrication methods
- 4 Advanced technologies to intensify the homogeneous amination process
- 5 Commercial use of homogeneous amination
- 6 Analysis of the flexibility of homogenous amination in polymer chemistry
- 7 Economic considerations for homogeneous amination reactions in polymer chemistry
- 8 Conclusion and future outlooks
- Abbreviations and symbols
- Part III. Homogeneous silicon compounds reactions
- Chapter 9. Hydrosilylation reactions with homogeneous catalysts
- 1 Introduction
- 1.1 Alkene hydrosilylation with homogeneous catalysts
- 2 Transition metal catalysts for hydrosilylation
- 2.1 Platinum catalysts for hydrosilylation
- 2.2 Iron catalysts for hydrosilylation
- 2.3 Manganese catalysts for hydrosilylation
- 2.4 Cobalt catalysts for hydrosilylation
- 3 Non-metal catalysts for hydrosilylation reactions
- 4 Conclusion future and outlooks
- Abbreviations and symbols
- Index
- No. of pages: 550
- Language: English
- Edition: 1
- Published: November 20, 2024
- Imprint: Elsevier
- Paperback ISBN: 9780443157127
- eBook ISBN: 9780443157134
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.
MM
Mohammad Amin Makarem
Dr. Mohammad Amin Makarem is a research associate at Taylor's University, Malaysia. He former worked 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 bio-template 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, as well as guest editing journals special issues.
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Tayebeh Roostaie
MM