Based on Collman et al.'s best-selling classic book, Principles and Applications of Organotransition Metal Chemistry, Hartwig's text consists of new or thoroughly updated and restructured chapters and provides an in-depth view into mechanism, reaction scope, and applications. It covers the most important developments in the field over the last twenty years with great clarity with a selective, but thorough and authoritative coverage of the fundamentals of organometallic chemistry, the elementary reactions of these complexes, and many catalytic processes occurring through organometallic intermediates, making this the Organotransition Metal Chemistry text for a new generation of scientists.
Although organotransition metal chemistry has been developing rapidly over the past 20 years, it is only recently that applications of transition metal complexes to organic synthesis have started to be exploited. This unique book provides an introduction to organometallic chemistry for chemists who have little or no experience in the field, describes the work that has already been done using organotransition metal complexes for synthesis, and indicates to organic and organometallic chemists the type of synthetic problems that can be solved using organometallic compounds. It covers all major advances that have been made in this rapidly expanding area of chemistry, including not only reactions that already have well established applications for synthesis but also many recently discovered potentially useful reactions, providing a survey of recent literature.
A systematic, readable treatment of organotransition metal chemistry that provides students, teachers, and practicing chemists with an understanding of basic concepts in catalysis and synthetic procedures using transition metal reagents. Covers basic principles of coordination chemistry, organometallic compounds of transition metals and non-transition metals, reactions, industrial applications, use in synthesis, methods of manipulation for air-sensitive compounds, and an overview of related topics. Well illustrated with figures and formulae.
Organotransition Metal Chemistry: A Mechanistic Approach describes a mechanistic approach to the study of the chemistry of organotransition metals. Organotransition metals are discussed in relation to their reactions with specific functional groups or types of compounds rather than by metals. Topics covered include the formation of hydrogen and carbon bonds to transition metals; reactions of transition metal δ- and π-bonded derivatives; and addition and elimination reactions of olefinic compounds. This book is comprised of 10 chapters and begins with a historical overview of organotransition metal chemistry, together with the unique chemistry of transition metals and mechanisms of ligand replacements. The following chapters discuss the methods of preparation of hydrido complexes and carbon-transition metal bonds; homogeneous hydrogenation reactions; isomerization, dimerization, oligomerization, and polymerization of olefins; and reactions of dienes, trienes, and tetraenes with transition metal compounds. Transition metal reactions with acetylenes and carbon monoxide as well as organic carbonyl compounds are also examined. This monograph should be of value to organic chemists as well as students and researchers of organic chemistry.
This book aims to introduce undergraduates to the utility of organotransition metal chemistry, a discipline of importance to scientists in a variety of industry sectors.
This textbook introduces students and experienced chemists to a rapidly growing interdisciplinary subject. It incorporates a thorough revision of the earlier edition, and includes all new developments.
Synthesis of Organotransition Metals.- Metallocarboranes: Past, Present, and Future.- Novel Rhodium and Palladium Complexes with Benzoyl and Thiobenzoyl Isocyanates as Ligands.- Polycyanovinyl Transition Metal Derivatives.- A New Preparation of Organocopper(I)-Isonitrile Complexes and Their Reactions.- An Unusual Behavior of?-Vinyl Alcohol Complexes of Transition Metals.- The Mode of Formation of Transition Metal to Carbon Bonds by Oxidative Addition.- Organoactinides: Coordination Patterns and Chemical Reactivity.- Recent Developments in Chemistry of Organolanthanides and Organoactinides.- C.
What do a pharmaceutical, polymer and solid state chemist have in common? Organometallic chemistry of course, since progress in their diverse fields has at many times relied on this. It is a discipline which stands at the crossroads of so many branches of chemistry, with industrial applications ranging from the gram to megatonne scale. Organotransition Metal Chemistry aims to introduce undergraduates to the utility of organotransition metal chemistry, a discipline of importance to scientists and technologists in a variety of industry sectors. The main focus will be on the reactivity of organometallic compounds of the transition metals, supported by discussion of structure and bonding and the implications. The aim, on completion of the course, is that a student will be equipped to recognize the key classes of organometallic compound, their methods of characterization, possible synthetic routes and anticipated reactivity.
Since the discovery of ferrocene and the sandwich-type complexes, the development of organometallic chemistry took its course like an avalanche and became one of the scientific success stories of the second half of the twentieth century. Based on this development, the traditional boundaries between inorganic and organic chemistry gradually disappeared and a rebirth of the nowadays highly important field of homogeneous catalysis occurred. It is fair to say that despite the fact that the key discovery, which sparked it all off, was made more than 50 years ago, organometallic chemistry remains a young and lively discipline.
This second edition offers easy access to the field of organotransition metal chemistry. The book covers the basics of transition metal chemistry, giving a practical introduction to organotransition reaction mechanisms.
Over the last decade, increased attention to reaction dynamics, combined with the intensive application of computers in chemical studies, mathematical modeling of chemical processes, and mechanistic studies has brought graph theory to the forefront of research. It offers an advanced and powerful formalism for the description of chemical reactions and their intrinsic reaction mechanisms. Chemical Reaction Networks: A Graph-Theoretical Approach elegantly reviews and expands upon graph theory as applied to mechanistic theory, chemical kinetics, and catalysis. The authors explore various graph-theoretical approaches to canonical representation, numbering, and coding of elementary steps and chemical reaction mechanisms, the analysis of their topological structure, the complexity estimation, and classification of reaction mechanisms. They discuss topologically distinctive features of multiroute catalytic and noncatalytic and chain reactions involving metal complexes. With it's careful balance of clear language and mathematical rigor, the presentation of the authors' significant original work, and emphasis on practical applications and examples, Chemical Reaction Networks: A Graph Theoretical Approach is both an outstanding reference and valuable tool for chemical research.