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Acid Halides to Ketones: Gilman Reagent01:14

Acid Halides to Ketones: Gilman Reagent

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Lithium dialkyl cuprate, also known as Gilman reagents, selectively reduces acid halides to ketones. The acid chloride is treated with Gilman reagent at −78 °C in the presence of ether solution to produce a ketone in good yield.
As shown below, the mechanism proceeds in two steps. First, one of the alkyl groups of the reagent acts as a nucleophile and attacks the acyl carbon of the acid chloride to form a tetrahedral intermediate. This is followed by the reformation of the carbon–oxygen...
3.7K
Elimination Reactions02:25

Elimination Reactions

16.3K
A nucleophile can react with an alkyl halide to give the substitution product by displacing the halogen. Or it can function as a base to give the elimination product by deprotonation of the neighboring carbon to form an alkene. In an elimination reaction, the substrate loses two groups from adjacent carbons forming at least one π bond. The carbon attached to the halogen is called the α carbon, while the adjacent carbon is called the β carbon; hence, these reactions are called...
16.3K
Benzene to 1,4-Cyclohexadiene: Birch Reduction Mechanism01:18

Benzene to 1,4-Cyclohexadiene: Birch Reduction Mechanism

2.5K
Birch reduction uses solvated electrons as reducing agents. The reaction converts benzene to 1,4-cyclohexadiene. The reaction proceeds by the transfer of a single electron to the ring to form a benzene radical anion. This anion is highly basic—it abstracts a proton from the alcohol to form a cyclohexadienyl radical. Another single electron transfer gives the cyclohexadienyl anion. A proton transfer from the alcohol forms 1,4-cyclohexadiene. Since this reduction occurs via radical anion...
2.5K
Nucleophilic Aromatic Substitution: Elimination–Addition01:11

Nucleophilic Aromatic Substitution: Elimination–Addition

4.9K
Simple aryl halides do not react with nucleophiles. However, nucleophilic aromatic substitutions can be forced under certain conditions, such as high temperatures or strong bases. The mechanism of substitution under such conditions involves the highly unstable and reactive benzyne intermediate. Benzyne contains equivalent carbon centers at both ends of the triple bond, each of which is equally susceptible to nucleophilic attack. This 50–50 distribution of products is...
4.9K
Amines to Alkenes: Cope Elimination01:14

Amines to Alkenes: Cope Elimination

2.3K
Cope elimination reaction involves the conversion of tertiary amines to alkene using hydrogen peroxide under thermal conditions, as depicted in figure 1.
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[3,3] Sigmatropic Rearrangement of 1,5-Dienes: Cope Rearrangement01:21

[3,3] Sigmatropic Rearrangement of 1,5-Dienes: Cope Rearrangement

3.2K
The Cope rearrangement is classified as a [3,3] sigmatropic shift in 1,5-dienes, leading to a more stable, isomeric 1,5-diene. The reaction involves a concerted movement of six electrons, four from two π bonds and two from a σ bond, via an energetically favorable chair-like transition state.
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Updated: Dec 22, 2025

[DPEPhosbcpCu]PF6: A General and Broadly Applicable Copper-Based Photoredox Catalyst
09:12

[DPEPhosbcpCu]PF6: A General and Broadly Applicable Copper-Based Photoredox Catalyst

Published on: May 21, 2019

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C(sp3) - CF3 Eliminación reductiva de un complejo de cobre neutro de cinco coordenadas

Shuanshuan Liu1,2, He Liu2, Shihan Liu3

  • 1Shandong Provincial Key Laboratory of Fluorine Chemistry and Chemical Materials, School of Chemistry and Chemical Engineering, University of Jinan, Jinan 250022, China.

Journal of the American Chemical Society
|May 5, 2020
PubMed
Resumen
Este resumen es generado por máquina.

Los investigadores aislaron un complejo de cobre estable que forma enlaces carbono-carbono a través de la eliminación reductora. Este proceso catalítico fundamental, previamente inexplorado para el cobre, ofrece nuevas vías para la síntesis química.

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Área de la Ciencia:

  • Química organometálica
  • Catálisis
  • Química sintética

Sus antecedentes:

  • La eliminación reductora de metales de transición tardía de alta valencia es crucial para la formación de enlaces C-C y C-heteroatomo en la catálisis.
  • Si bien se estudió para Pt (IV), Pd (IV), Ni (III) / Ni (IV) y Au (III), la eliminación reductora de los complejos neutrales Cu (III) está en gran parte inexplorada.

Objetivo del estudio:

  • Informar sobre el aislamiento y la reactividad de un complejo Cu (III) estable y neutro.
  • Investigar la vía de eliminación reductiva de este nuevo complejo Cu (III) para la formación de enlaces C-C.

Principales métodos:

  • Aislamiento y caracterización de un complejo piramidal Cu (III) cuadrado de cinco coordenadas.
  • Determinación cuantitativa del rendimiento del producto de eliminación reductivo (CH3-CF3).
  • Estudios mecanicistas para elucidar la vía de reacción.

Principales resultados:

  • Se ha aislado con éxito un complejo cuadrado piramidal Cu (III) de cinco coordenadas.
  • El complejo Cu (III) se sometió a una eliminación reductora para obtener CH3-CF3 en rendimiento cuantitativo.
  • Los estudios mecánicos indicaron un proceso sincrónico de ruptura / formación de enlaces a través de un estado de transición de anillo de tres miembros.

Conclusiones:

  • Se ha demostrado la viabilidad de la eliminación reductiva a partir de un complejo Cu (III) neutro.
  • Estableció una nueva ruta sintética para la formación de enlaces C-C utilizando la catálisis del cobre.
  • Proporcionó una visión mecanicista del proceso de eliminación reductora que involucra un estado de transición de anillo de tres miembros.