Save up to 30% on Elsevier print and eBooks with free shipping. No promo code needed.
Save up to 30% on print and eBooks.
Progress in Heterocyclic Chemistry
1st Edition, Volume 27 - October 3, 2015
Editors: Gordon Gribble, John A. Joule
Language: English
Hardback ISBN:9780081000243
9 7 8 - 0 - 0 8 - 1 0 0 0 2 4 - 3
eBook ISBN:9780081000472
9 7 8 - 0 - 0 8 - 1 0 0 0 4 7 - 2
Progress in Heterocyclic Chemistry (PHC), Volume 27, is an annual review series commissioned by the International Society of Heterocyclic Chemistry (ISHC). Volumes in the serie…Read more
Purchase options
LIMITED OFFER
Save 50% on book bundles
Immediately download your ebook while waiting for your print delivery. No promo code is needed.
Progress in Heterocyclic Chemistry (PHC), Volume 27,
is an annual review series commissioned by the International Society of Heterocyclic Chemistry (ISHC). Volumes in the series contain both highlights of the previous year’s literature on heterocyclic chemistry and articles on new developing topics of particular interest to heterocyclic chemists.
The highlight chapters in Volume 27 are all written by leading researchers and these chapters constitute a systematic survey of the important original material reported in the literature of heterocyclic chemistry in 2014. Additional articles in this volume are “The Use of Propargyl Vinyl Ethers in Heterocycle Synthesis” and “Recent Progress of Phosphonium Coupling in Heterocyclic and Medicinal Chemistry."
As with previous volumes in the series, Volume 27 will enable academic and industrial chemists, and advanced students, to keep abreast of developments in heterocyclic chemistry in a convenient way.
Recognized as the premiere review of heterocyclic chemistry
Includes contributions from leading researchers in the field
Provides a systematic survey of the important 2014 heterocyclic chemistry literature
Includes articles on new developing topics of interest to heterocyclic chemists
Organic chemists, academic and industrial chemists, as well as advanced students
Foreword
Editorial Advisory Board Members Progress in Heterocyclic Chemistry
Chapter 1. Propargyl Vinyl Ethers as Powerful Starting Points for Heterocycle Synthesis
1.1. Introduction
1.2. Synthesis of Furans and Pyrroles via Propargyl Claisen Rearrangement
1.3. Synthesis of 1,3-Oxazolidines via Microwave Synthesis
1.4. Synthesis of 2H-Pyrans and 1,2-Dihydropyridines
1.5. Summary
Chapter 2. Recent Progress of Phosphonium Coupling in Heterocyclic and Medicinal Chemistry
2.1. Introduction
2.2. Discovery of Phosphonium Coupling
2.3. Phosphonium Coupling for Direct Amination
2.4. Phosphonium Coupling for Direct Etherification
2.5. Phosphonium Coupling for Direct Thioetherification
2.6. Phosphonium Coupling for Direct Alkylation
2.7. Phosphonium Coupling for Direct Arylation
2.8. Phosphonium Coupling for Direct Alkynylation
2.9. Phosphonium Coupling for Nucleoside Chemistry
2.10. Summary
Chapter 3. Three-Membered Ring Systems
3.1. Introduction
3.2. Epoxides
3.3. Aziridines
Chapter 4. Four-Membered Ring Systems
4.1. Introduction
4.2. Azetidines, Azetines, and Related Systems
4.3. Monocyclic 2-Azetidinones (β-Lactams)
4.4. Fused and Spirocyclic β-Lactams
4.5. Oxetanes, Dioxetanes, and 2-Oxetanones (β-Lactones)
4.6. Thietanes and Related Systems
4.7. Silicon and Phosphorus Heterocycles: Miscellaneous
Chapter 5.1. Five-Membered Ring Systems: Thiophenes and Se/Te Derivatives
5.1.1. Introduction
5.1.2. Synthesis of Thiophenes, Selenophenes, and Tellurophenes
5.1.3. Elaboration of Thiophenes and Benzothiophenes
5.1.4. Synthesis of Thiophenes, Selenophenes, and Tellurophenes for the Use in the Material Sciences
5.1.5. Thiophene, Selenophene, and Tellurophene Derivatives in Medicinal and Environmental Chemistry
Chapter 5.2. Five-Membered Ring Systems: Pyrroles and Benzo Analogs
5.2.1. Introduction
5.2.2. Synthesis of Pyrroles
5.2.3. Reactions of Pyrroles
5.2.4. Synthesis of Indoles
5.2.5. Reactions of Indoles
5.2.6. Isatins, Oxindoles, Indoxyls, and Spirooxindoles
5.2.7. Carbazoles
5.2.8. Azaindoles
5.2.9. Isoindoles
Chapter 5.3. Five-Membered Ring Systems: Furans and Benzofurans
5.3.1. Introduction
5.3.2. Reactions
5.3.3. Synthesis
Chapter 5.4. Five-Membered Ring Systems: With More than One N Atom
5.4.1. Introduction
5.4.2. Pyrazoles and Ring-Fused Derivatives
5.4.3. Imidazoles and Ring-Fused Derivatives
5.4.4. 1,2,3-Triazoles and Ring-Fused Derivatives
5.4.5. 1,2,4-Triazoles and Ring-Fused Derivatives
5.4.6. Tetrazoles and Ring-Fused Derivatives
Chapter 5.5. Five-Membered Ring Systems: With N and S Atom
5.5.1. Introduction
5.5.2. Thiazoles
5.5.3. Isothiazoles
Chapter 5.6. Five-Membered Ring Systems: With O and S (Se, Te) Atoms
5.6.1. 1,3-Dioxoles and Dioxolanes
5.6.2. 1,3-Dithioles and Dithiolanes
5.6.3. 1,3-Oxathioles and Oxathiolanes
5.6.4. 1,2-Dioxolanes
5.6.5. 1,2-Dithioles and Dithiolanes
5.6.6. 1,2-Oxaselenolanes
5.6.7. Three Heteroatoms
Chapter 5.7. Five-Membered Ring Systems: With O and N Atoms
5.7.1. Isoxazoles
5.7.2. Isoxazolines
5.7.3. Isoxazolidines
5.7.4. Oxazoles
5.7.5. Oxazolines
5.7.6. Oxazolidines
5.7.7. Oxadiazoles
Chapter 6.1. Six-Membered Ring Systems: Pyridine and Benzo Derivatives
6.1.1. Introduction
6.1.2. Overview of Pyridine and (Iso)quinoline Uses
6.1.3. Synthesis of Pyridines
6.1.4. Reactions of Pyridines
6.1.5. Synthesis of Isoquinolines
6.1.6. Reactions of Isoquinolines
Chapter 6.2. Six-Membered Ring Systems: Diazines and Benzo Derivatives
6.2.1. Introduction
6.2.2. Pyridazines and Benzo Derivatives
6.2.3. Pyrimidines and Benzo Derivatives
6.2.4. Pyrazines and Its Benzo Derivatives
Chapter 6.3. Triazines and Tetrazines
6.3.1. Triazines
6.3.2. Tetrazines
Chapter 6.4. Six-Membered Ring Systems: With O and/or S Atoms
6.4.1. Introduction
6.4.2. Heterocycles Containing One Oxygen Atom
6.4.3. Heterocycles Containing One or Two Sulfur Atoms
6.4.4. Heterocycles Containing Two or More Oxygen Atoms
6.4.5. Heterocycles Containing Both Oxygen and Sulfur in the Same Ring
Chapter 7. Seven-Membered Rings
7.1. Introduction
7.2. Seven-Membered Systems Containing One Heteroatom
7.3. Seven-Membered Systems Containing Two Heteroatoms
7.4. Seven-Membered Systems Containing Three or More Heteroatoms
7.5. Future Directions
Chapter 8. Eight-Membered and Larger Rings
8.1. Introduction
8.2. Carbon–Oxygen Rings
8.3. Carbon–Nitrogen Rings
8.4. Carbon–Sulfur Rings
8.5. (Carbon–Nitrogen)–(Carbon–Oxygen) Rings
8.6. Carbon–Nitrogen–Oxygen Rings
8.7. Carbon–Nitrogen–Sulfur/Selenium Rings
8.8. Carbon–Oxygen–Sulfur Rings
8.9. Carbon–Nitrogen–Metal Rings
Index
No. of pages: 640
Language: English
Edition: 1
Volume: 27
Published: October 3, 2015
Imprint: Elsevier
Hardback ISBN: 9780081000243
eBook ISBN: 9780081000472
GG
Gordon Gribble
Gordon Gribble is the Dartmouth Professor of Chemistry at Dartmouth College, Hanover, USA. His research program covers several areas of organic chemistry, most of which involve synthesis, including novel indole chemistry, triterpenoid synthesis, DNA intercalation, and new synthetic methodology. Prof. Gribble also has a deep interest in naturally occurring organohalogen compounds and in the chemistry of wine and wine making.
Affiliations and expertise
Professor, Chemistry, Dartmouth College, Hanover, USA
JJ
John A. Joule
John Arthur Joule did his BSc, MSc, and PhD degrees at The University of Manchester, obtaining his PhD in 1961. He then undertook post-doctoral work at Princeton University and Stanford University, before joining the academic staff of the Chemistry Department at The University of Manchester in 1963, where he is currently a Professor. In 1996 he received an RSC Medal for Heterocyclic Chemistry.
Affiliations and expertise
Emeritus Professor, The University of Manchester, UK
Read Progress in Heterocyclic Chemistry on ScienceDirect