Science of Synthesis provides a critical review of the synthetic methodology developed from the early 1800s to date for the entire field of organic and organometallic chemistry. As the only resource providing full-text descriptions of organic transformations and synthetic methods as well as experimental procedures, Science of Synthesis is therefore a unique chemical information tool. Over 1000 world-renowned experts have chosen the most important molecular transformations for a class of organic compounds and elaborated on their scope and limitations. The systematic, logical and consistent organization of the synthetic methods for each functional group enables users to quickly find out which methods are useful for a particular synthesis and which are not. Effective and practical experimental procedures can be implemented quickly and easily in the lab.// The content of this e-book was originally published in December 2005.

Auteur
Victor Snieckus, M. Majewski, Barry M. Trost

Résumé

Science of Synthesis: Houben-Weyl Methods of Molecular Transformations is the entirely new edition of the acclaimed reference series Houben-Weyl, the standard synthetic chemistry resource since 1909. This new edition is published in English and will comprise 48 volumes published between the years 2000 and 2008.

Science of Synthesis is a quality reference work developed by a highly esteemed editorial board to provide a comprehensive and critical selection of reliable organic and organometallic synthetic methods. This unique resource is designed to be the first point of reference when searching for a synthesis strategy.

Contains the expertise of presently 400 leading chemists worldwide
Critically evaluates the preparative applicability and significance of the synthetic methods
Discusses relevant background information and provides detailed experimental procedures For full information on the Science of Synthesis series, visit the Science of Synthesis Homepage

Contenu

8.2 Product Class 2: Sodium Compounds
8.2.1 Product Subclass 1: Sodium Metal and Sodium–Potassium Alloy
8.2.2 Product Subclass 2: Sodium Hydride
8.2.3 Product Subclass 3: Sodium Halides and Sodium Cyanide
8.2.4 Product Subclass 4: Sodium–Oxygen Compounds
8.2.5 Product Subclass 5: Sodium–Nitrogen Compounds
8.2.6 Product Subclass 6: Alkylsodium Compounds
8.2.7 Product Subclass 7: Alkenylsodium Compounds
8.2.8 Product Subclass 8: Sodium Acetylides
8.2.9 Product Subclass 9: Allylsodium Compounds
8.2.10 Product Subclass 10: Arylsodium Compounds and Sodium Cyclopentadienide
8.2.11 Product Subclass 11: Benzylsodium Compounds
8.2.12 Product Subclass 12: 1,1-Disubstituted Organosodium Compounds
8.2.13 Product Subclass 13: 1-Monosubstituted Organosodium Compounds
8.2.14 Product Subclass 14: α-Sodiocarboxylic Acids and Related Sodium Compounds
8.2.15 Product Subclass 15: α-Sodio Aldehydes, α-Sodio Ketones, and Related Compounds
8.3 Product Class 3: Potassium Compounds
8.3.1 Product Subclass 1: Potassium Metal
8.3.2 Product Subclass 2: Potassium Hydride
8.3.3 Product Subclass 3: Potassium Halides, Potassium Cyanide, and Potassium Carbonate
8.3.4 Product Subclass 4: Potassium Hydroxide and Potassium Alkoxides
8.3.5 Product Subclass 5: Potassium–Sulfur, –Selenium, and –Tellurium Compounds
8.3.6 Product Subclass 6: Potassium Amides and Phosphides
8.3.7 Product Subclass 7: Organometallic Compounds of Potassium
8.4 Product Class 4: Rubidium and Cesium Compounds
8.4.1 Product Subclass 1: Rubidium and Cesium Metals
8.4.2 Product Subclass 2: Rubidium and Cesium Halides
8.4.3 Product Subclass 3: Rubidium and Cesium Carbonates
8.4.4 Product Subclass 4: Organometallic Compounds of Rubidium and Cesium