Gas-Phase Pyrolytic Reactions - Synthesis, Mechanisms, and Kinetics

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Offers a physical organic chemistry and mechanistic perspective of the chemistry of thermal processes in the gas phase
 
The book looks at all aspects of the chemical processing technique called gas-phase pyrolysis, including its methodology and reactors, synthesis, reaction mechanisms, structure, kinetics, and applications. It discusses combinations of pyrolytic reactors with physiochemical techniques, routes for and reactions for the synthesis of organic compounds, and the control of reaction rates.
 
Gas-Phase Pyrolytic Reactions: Synthesis, Mechanisms, and Kinetics starts with in-depth chapter coverage of static pyrolysis, dynamic flow pyrolysis, and analytical pyrolysis. It then examines synthesis and applications, including flash vacuum pyrolysis in organic synthesis, elimination of HX, elimination of CO and CO2, pyrolysis of Meldrum's acid derivatives, and elimination of N2. A chapter on reaction mechanism comes next and includes coverage of retero-ene reaction and reactive intermediates. Following that are sections covering: structure/reactivity correlation, functional group & structural frame interconversions; gas-phase pyrolysis of hydrazones and phosphorus Ylides; and more.
* Deals with a growing area of chemistry and engineering interest that fits under the practices of green and sustainable chemistry
* Addresses several important aspects: methodology and reactors, synthesis, reaction mechanisms, structure, kinetics, and applications
* Reviews general methods of pyrolysis techniques
* Sets out the fundamentals and advantages of gas-phase pyrolysis in a way that illustrates its wide potential applications
 
Gas-Phase Pyrolytic Reactions: Synthesis, Mechanisms, and Kinetics will appeal to organic chemists, physical organic chemists, chemical engineers and anyone interested in green/sustainable chemistry, chemical synthesis, or process chemistry.

List of contents

Preface xi
 
List of Abbreviations xiii
 
About the Author xv
 
1 Methodologies and Reactors 1
 
1.1 Static Pyrolysis 1
 
1.1.1 Sealed-Tube Reactor 2
 
1.1.1.1 Pyrolyzer 2
 
1.1.1.2 Reaction Tube 3
 
1.1.1.3 Kinetic Studies 3
 
1.1.1.4 Treatment of Kinetic Results 4
 
1.1.2 Static Apparatus 5
 
1.1.2.1 Reaction Chamber 6
 
1.1.2.2 The Pyrolysis Method 7
 
1.1.2.3 Treatment of the Results 7
 
1.2 Dynamic Flow Pyrolysis 8
 
1.2.1 Flash Vacuum Pyrolysis 8
 
1.2.2 Synthetic Applications of FVP 10
 
1.2.3 Gas-Flow Pyrolysis vs. STP 13
 
1.2.4 Limitations of FVP 13
 
1.2.5 Spray Pyrolysis 14
 
1.2.6 Falling-Solid Pyrolysis 17
 
1.3 Analytical Pyrolysis 19
 
1.3.1 Pyrolysis Gas Chromatography (Py-GC) 19
 
1.3.1.1 Online Py-GC 20
 
1.3.2 Pyrolysis Mass Spectrometry 22
 
1.3.2.1 Online Pyrolysis Gas Chromatography/Mass Spectrometry (Py-GC/MS) 22
 
1.3.3 FVP with Spectroscopy 22
 
1.3.4 Catalytic Gas-Phase Pyrolysis 24
 
References 27
 
2 Synthesis and Applications 31
 
2.1 Flash Vacuum Pyrolysis in Organic Synthesis 31
 
2.2 Elimination of HX 34
 
2.3 Elimination of CO and CO2 38
 
2.4 Pyrolysis of Meldrum's Acid Derivatives 54
 
2.5 Elimination of N2 60
 
2.5.1 Deazetization Reactions of Allylic Diazenes 63
 
2.5.2 Pyrolysis of Benzotriazole Derivatives 65
 
2.5.3 Pyrolysis of Triazine Derivatives 68
 
References 72
 
3 Reaction Mechanism 79
 
3.1 Retro-ene Reactions 79
 
3.1.1 Acetylenic Compounds 80
 
3.1.2 Acyl Group Participation 82
 
3.1.3 Cyanates and Isocyanates 82
 
3.1.4 Esters 83
 
3.1.5 Amides 88
 
3.1.5.1 Acetamides and Thioacetamides 88
 
3.1.5.2 Benzamides 92
 
3.1.5.3 N-Substituted Amides 93
 
3.2 Reactive Intermediates 94
 
3.2.1 Radicals 94
 
3.2.2 Diradicals 97
 
3.2.3 Benzynes 98
 
3.2.3.1 o-Benzynes 99
 
3.2.3.2 m- and p-Benzynes 101
 
3.2.4 Carbenes 101
 
3.2.5 Nitrenes 108
 
References 120
 
4 Structure/Reactivity Correlation 127
 
4.1 Diketones 127
 
4.2 Cyanoketones 133
 
4.3 Ketoamides 135
 
4.4 Benzotriazoles 136
 
4.5 Hammett Correlation in Gas-Phase Pyrolysis 148
 
4.6 Alkoxy versus Amino Group 153
 
4.6.1 Neighboring Group Participation 155
 
4.6.2 Amino Esters 158
 
References 162
 
5 Functional Group and Structural Frame Interconversions 167
 
5.1 Functional Group Interconversion 167
 
5.1.1 Thermal Retro-Ene Reactions 167
 
5.1.1.1 alpha-Substituted Carboxylic Acids 173
 
5.1.1.2 2-Hydroxycarboxylic Acids 175
 
5.1.1.3 2-Alkoxycarboxylic Acids 176
 
5.1.1.4 2-Phenoxycarboxylic Acids 177
 
5.1.1.5 2-Aminocarboxylic Acids 180
 
5.1.1.6 2-Acetooxycarboxylic Acids 182
 
5.1.1.7 2-Ketocarboxylic Acids 184
 
5.1.1.8 alpha-Substituted Esters 186
 
5.1.1.9 ß-Substituted Carboxylic Acids 188
 
5.2 Structural Frame Interconversion 191
 
5.2.1 Alkyl Heterocycles 195
 
References 197
 
6 Gas-Phase Pyrolysis of Hydrazones 201
 
6.1 Substituted Phenylhydrazones 203
 
6.2 N-Arylidineamino Heterocycles 213
 
6.3 Arylidene Hydrazine Heterocycles 221
 
References 231
 
7 Gas-Phase Pyrolysis of Phosphorus Ylides 235
 
7.1 Synthetic Applications 235
 

About the author

NOURIA A. AL-AWADI is Professor of Organic Chemistry at Kuwait University, Safat, State of Kuwait. She is a Chartered Chemist and Fellow of the Royal Society of Chemistry and has over 150 peer-reviewed journal papers published.

Summary

This book covers a chemical processing technique, gas-phase pyrolysis, that has garnered great interest in recent years as a benign synthetic method for green chemistry. The book looks at all aspects of gas-phase pyrolysis: structure, kinetics, mechanisms, empirical and theoretical investigations, synthesis, materials, and potential applications.