Topic
Alkene
About: Alkene is a research topic. Over the lifetime, 13898 publications have been published within this topic receiving 348061 citations. The topic is also known as: alkenes.
Papers published on a yearly basis
1 / 2
Papers
26 Jul 2002
TL;DR: Palladium-CATALYZED Reactions Involving Nucleophilic Attack on -Ligands of Palladium-Alkene, PalladiumAlkyne, and Related Derivatives as mentioned in this paper.
Abstract: PREFACE. CONTRIBUTORS. INTRODUCTION AND BACKGROUND. Historical Background of Organopalladium Chemistry Fundamental Properties of Palladium and Patterns of the Reactions of Palladium and Its Complexes. PALLADIUM COMPOUNDS: STOICHIOMETRIC PREPARATION, IN SITU GENERATION, AND SOME PHYSICAL AND CHEMICAL PROPERTIES. Background for Part II. Pd(0) and Pd(II) Compounds Without Carbon-Palladium Bonds. Organopalladium Compounds Containing Pd(0) and Pd(II). Palladium Complexes Containing Pd(I), Pd(III), or Pd(IV). PALLADIUM-CATALYZED REACTIONS INVOLVING REDUCTIVE ELIMINATION. Background for Part III. Palladium-Catalyzed Carbon-Carbon Cross-Coupling. Palladium-Catalyzed Carbon-Hydrogen and Carbon- Heteroatom Coupling. PALLADIUM-CATALYZED REACTIONS INVOLVING CARBOPALLADATION. Background for Part IV. The Heck Reaction (Alkene Substitution via Carbopalladation- Dehydropalladation) and Related Carbopalladation Reactions. Palladium-Catalyzed Tandem and Cascade Carbopalladation of Alkynes and 1,1-Disubstituted Alkenes. Allylpalladation and Related Reactions of Alkenes, Alkynes, Dienes, and Other -Compounds. Alkynyl Substitution via Alkynylpalladation-Reductive Elimination. Arene Substitution via Addition-Elimination. Carbopalladation of Allenes. Synthesis of Natural Products via Carbopalladation. Cyclopropanation and Other Reactions of Palladium-Carbene (and Carbyne) Complexes. Carbopalladation via Palladacyclopropanes and Palladacyclopropenes. Palladium-Catalyzed Carbozincation. PALLADIUM-CATALYZED REACTIONS INVOLVING NUCLEOPHILIC ATTACK ON LIGANDS. Background for Part V. Palladium-Catalyzed Nucleophilic Substitution Involving Allylpalladium, Propargylpalladium, and Related Derivatives. Palladium-Catalyzed Reactions Involving Nucleophilic Attack on -Ligands of Palladium-Alkene, Palladium-Alkyne, and Related Derivatives. PALLADIUM-CATALYZED CARBONYLATION AND OTHER RELATED REACTIONS INVOLVING MIGRATORY INSERTION. Background for Part VI. Migratory Insertion Reactions of Alkyl-, Aryl-, Alkenyl-, and Alkynylpalladium Derivatives Involving Carbon Monoxide and Related Derivatives. Migratory Insertion Reactions of Allyl, Propargyl, and Allenylpalladium Derivatives Involving Carbon Monoxide and Related Derivatives. Acylpalladation and Related Addition Reactions. Other Reactions of Acylpalladium Derivatives. Synthesis of Natural Products via Palladium-Catalyzed Carbonylation. Palladium-Catalyzed Carbonylative Oxidation. Synthesis of Oligomeric and Polymeric Materials via Palladium-Catalyzed Successive Migratory Insertion of Isonitriles. CATALYTIC HYDROGENATION AND OTHER PALLADIUM-CATALYZED REACTIONS VIA HYDROPALLADATION, METALLOPALLADATION, AND OTHER RELATED SYN ADDITION REACTIONS WITHOUT CARBON-CARBON BOND FORMATION OR CLEAVAGE. Background for Part VII. Palladium-Catalyzed Hydrogenation. Palladium-Catalyzed Isomerization of Alkenes, Alkynes, and Related Compounds without Skeletal Rearrangements. Palladium-Catalyzed Hydrometallation. Metallopalladation. Palladium-Catalyzed Syn-Addition Reactions of X-Pd Bonds (X = Group 15, 16, and 17 Elements). PALLADIUM-CATALYZED OXIDATION REACTIONS THAT HAVE NOT BEEN DISCUSSED IN EARLIER PARTS. Background for Part VIII. Oxidation via Reductive Elimination of Pd(II) and Pd(IV) Complexes. Palladium-Catalyzed or -Promoted Oxidation via 1,2- or 1,4-Elimination. Other Miscellaneous Palladium-Catalyzed or -Promoted Oxidation Reactions. REARRANGEMENT AND OTHER MISCELLANEOUS REACTIONS CATALYZED BY PALLADIUM. Background for Part IX. Rearrangement Reactions Catalyzed by Palladium. TECHNOLOGICAL DEVELOPMENTS IN ORGANOPALLADIUM CHEMISTRY. Aqueous Palladium Catalysis. Palladium Catalysts Immobilized on Polymeric Supports. Organopalladium Reactions in Combinatorial Chemistry. REFERENCES. General Guidelines on References Pertaining to Palladium and Organopalladium Chemistry. Books (Monographs). Reviews and Accounts (as of September 1999). SUBJECT INDEX.
3,242 citations
TL;DR: The fascinating story of olefin (or alkene) metathesis began almost five decades ago, when Anderson and Merckling reported the first carbon-carbon double-bond rearrangement reaction in the titanium-catalyzed polymerization of norbornene.
Abstract: The fascinating story of olefin (or alkene) metathesis (eq
1) began almost five decades ago, when Anderson and
Merckling reported the first carbon-carbon double-bond
rearrangement reaction in the titanium-catalyzed polymerization of norbornene. Nine years later, Banks and Bailey reported “a new disproportionation reaction . . . in which olefins are converted to homologues of shorter and longer carbon chains...”. In 1967, Calderon and co-workers named this metal-catalyzed redistribution of carbon-carbon double bonds olefin metathesis, from the Greek word “μeτάθeση”, which means change of position. These contributions have since served as the foundation for an amazing research field, and olefin metathesis currently represents a powerful transformation in chemical synthesis, attracting a vast amount of interest both in industry and academia.
1,921 citations
Book•
1 Jan 1980
TL;DR: A perspective survey of organotransition metal complexes according to ligand substitution processes can be found in this paper, with a focus on transition metal complexes with metal carbon-bonded ligands.
Abstract: A perspective Bonding Survey of organotransition metal complexes according to ligand Ligand substitution processes Oxidative-addition and reductive elimination Intramolecular insertion reactions Nucleophilic attack on ligands coordinated to transition metals Electrophilic attacks on coordinated ligands Metallacycles Homogeneous catalytic hydrogenation, hydrosilation, and hydrocyanation Catalytic polymerization of olefins and acetylenes Catalytic reactions involving carbon monoxide Synthetic applications of transition metal hydrides Synthetic applications of transition metal complexes containing metal carbon bonds Synthetic applications of transition metal carbonyl compounds Synthetic application of transition metal carbenes and metallacycles Synthetic applications of transition metal alkene, diene, and duenyl complexes Synthetic applications of transition metal alkyne complexes Synthetic applications of -allyl transition metal complexes Synthetic applications of transition metal arene complexes.
1,831 citations
TL;DR: Gold(I) complexes selectively activate π-bonds of alkenes in complex molecular settings, which has been attributed to relativistic effects as discussed by the authors, and are the most effective catalysts for the electrophilic activation of alkynes under homogeneous conditions.
Abstract: 1.1. General Reactivity of Alkyne-Gold(I) Complexes
For centuries, gold had been considered a precious, purely decorative inert metal. It was not until 1986 that Ito and Hayashi described the first application of gold(I) in homogeneous catalysis.1 More than one decade later, the first examples of gold(I) activation of alkynes were reported by Teles2 and Tanaka,3 revealing the potential of gold(I) in organic synthesis. Now, gold(I) complexes are the most effective catalysts for the electrophilic activation of alkynes under homogeneous conditions, and a broad range of versatile synthetic tools have been developed for the construction of carbon–carbon or carbon–heteroatom bonds.
Gold(I) complexes selectively activate π-bonds of alkynes in complex molecular settings,4−10 which has been attributed to relativistic effects.11−13 In general, no other electrophilic late transition metal shows the breadth of synthetic applications of homogeneous gold(I) catalysts, although in occasions less Lewis acidic Pt(II) or Ag(I) complexes can be used as an alternative,9,10,14,15 particularly in the context of the activation of alkenes.16,17 Highly electrophilic Ga(III)18−22 and In(III)23,24 salts can also be used as catalysts, although often higher catalyst loadings are required.
In general, the nucleophilic Markovnikov attack to η2-[AuL]+-activated alkynes 1 forms trans-alkenyl-gold complexes 2 as intermediates (Scheme 1).4,5a,9,10,12,25−29 This activation mode also occurs in gold-catalyzed cycloisomerizations of 1,n-enynes and in hydroarylation reactions, in which the alkene or the arene act as the nucleophile.
Scheme 1
Anti-Nucleophilic Attack to η2-[AuL]+-Activated Alkynes
1,479 citations
TL;DR: The catalytic production of organic molecules is one of the most important applications of organometallic chemistry and enantioselective syntheses of molecules bearing an amine functionality use classical stoichiometric reactions with chiral auxiliaries or utilize enantiomerically pure starting material.
Abstract: The catalytic production of organic molecules is one of the most important applications of organometallic chemistry. For this purpose the distinct reaction chemistry of organic ligands covalently bound to transition metals is exploited. Most organometallic chemistry has focused on the formation of carboncarbon or carbon-hydrogen bonds. The platinum group metals, in particular Pd and Rh, have been the most commonly used elements insfrequently commercializedscatalytic processes that include hydrogenation, hydroformylation and others. On the other hand, carbon-oxygen and carbon-nitrogen bonds are found in the majority of organic molecules and are of particular importance in physiologically active substances. However, catalytic organometallic reactions that lead to the formation of carbonheteroatom bonds are less common.1,2 The catalytic construction of carbon-nitrogen bonds in amines is particularly rare.3-10 Clearly, efficient catalytic routes to nitrogen based molecules are of great interest.11 Especially useful are catalytic hydroaminations of olefins and alkynes which avoid production of byproducts, like salts, generally observed in metal-catalyzed aminations of C-X derivatives (X ) e.g., halogen). However, known aminations of olefins often require stoichiometric use of transition metals and general methods for carrying out aminations catalytically are not yet available.12,13 Most of the present enantioselective syntheses of molecules bearing an amine functionality use classical stoichiometric reactions with chiral auxiliaries or utilize enantiomerically pure starting material.14-16 Hydroamination of alkenes and alkynes, which constitutes the formal addition of a N-H bond across a carbon-carbon multiple bond (Scheme 1), is a transformation of seemingly fundamental simplicity and would appear to offer the most attractive route to numerous classes of organo-nitrogen molecules such as alkylated amines, enamines or imines. Organic chemists have developed various synthetic approaches for the amination of olefins.17-19 Direct addition of nucleophiles H-NR2 to activated alkenes is of general importance for the synthesis of compounds with nitrogen atoms â to groups such as keto, ester, nitrile, sulfoxide, or nitro.13,20-23 These additions usually lead to the anti-Markovnikov products. On the other hand aliphatic olefins as well as most aromatic olefins are often aminated to give the Markovnikov product. One possibility to reverse the reactivity of aliphatic olefins is the use of electrophilic nitrogen radicals which have been used to obtain anti-Markovnikov products.24 In the past much work has been done on the activation of alkenes with stoichiometric amounts of metal.24 Reactions are mostly promoted by complexes of titanium,25 iron,26 zirconium,27 palladium28-31 and mercury.32,33 However, catalytic additions of amines H-NR2 to nonactivated double or triple bonds are still rare. Two basic approaches have been employed to catalytically effect aminations and involve either alkene/alkyne or amine activation routes (Scheme 2).34,140 Alkene activation is generally accomplished with late-transition-metal catalysts, which render coordinated olefins more susceptible to attack by † Dedicated to Dipl. Chem. Martin Eichberger (deceased 11/20/ 1997). 675 Chem. Rev. 1998, 98, 675−703
1,268 citations
Related Topics (5)
Performance Metrics
| Year | Papers |
|---|---|
| 2026 | 5 |
| 2025 | 209 |
| 2024 | 325 |
| 2023 | 591 |
| 2022 | 742 |
| 2021 | 517 |