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Radical Substitution: Hydrogenolysis of Alkyl Halides with Tributyltin Hydride01:26

Radical Substitution: Hydrogenolysis of Alkyl Halides with Tributyltin Hydride

Radical substitution reactions can be used to remove functional groups from molecules. The hydrogenolysis of alkyl halides is one such reaction, where the weak Sn–H bond in tributyltin hydride reacts with alkyl halides to form alkanes. Here, the reagent Bu3SnH yields tributyltin halide as a byproduct.
The bonds formed in this reaction are stronger than the bonds broken, making it energetically favorable. The reaction follows a radical chain mechanism similar to radical halogenation reactions,...
Acid Halides to Alcohols: LiAlH4 Reduction01:19

Acid Halides to Alcohols: LiAlH4 Reduction

Acid halides are reduced to alcohols in the presence of a strong reducing agent like lithium aluminum hydride.
The mechanism proceeds in three steps. First, the nucleophilic hydride ion attacks the carbonyl carbon of the acid halide to form a tetrahedral intermediate. Next, the carbonyl group is re-formed, and the halide ion departs as a leaving group, generating an aldehyde. A second nucleophilic attack by the hydride yields an alkoxide ion, which, upon protonation, gives a primary alcohol as...
Radical Formation: Elimination00:51

Radical Formation: Elimination

Another method of radical formation is the elimination process. It is the opposite of the addition route and is driven by the instability of the radical. For example, as depicted in Figure 1, dibenzoyl peroxide yields a pair of unstable radicals upon homolysis. Given its instability, this radical spontaneously undergoes elimination via a C–C bond cleavage to form a relatively more stable phenyl radical. The mechanism involves cleavage of the bond between the α and β positions with respect to...
Benzene to 1,4-Cyclohexadiene: Birch Reduction Mechanism01:18

Benzene to 1,4-Cyclohexadiene: Birch Reduction Mechanism

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...
Elimination Reactions02:25

Elimination Reactions

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 β elimination or...
Redox Titration: Other Oxidizing and Reducing Agents01:26

Redox Titration: Other Oxidizing and Reducing Agents

Besides iodine, other oxidizing or reducing agents can serve as titrants in redox titrations. Common oxidizing titrants include KMnO4, cerium(IV), and K2Cr2O7. The choice of oxidizing titrants depends on factors like stability, cost, analyte strength, and reaction rate between the analyte and titrant. KMnO4 is a strong oxidizing titrant that reduces from Mn(VII) to Mn(II) in a highly acidic solution, simultaneously oxidizing the analyte to a higher oxidation state. In this case, KMnO4 acts as a...

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Updated: Jun 8, 2026

Line Shape Analysis of Dynamic NMR Spectra for Characterizing Coordination Sphere Rearrangements at a Chiral Rhenium Polyhydride Complex
10:52

Line Shape Analysis of Dynamic NMR Spectra for Characterizing Coordination Sphere Rearrangements at a Chiral Rhenium Polyhydride Complex

Published on: July 27, 2022

Eliminación reductora bimetálica de complejos dinucleares de Pd (III)

David C Powers1, Diego Benitez, Ekaterina Tkatchouk

  • 1Department of Chemistry and Chemical Biology, Harvard University, 12 Oxford Street, Cambridge, Massachusetts 02138, USA.

Journal of the American Chemical Society
|September 23, 2010
PubMed
Resumen
Este resumen es generado por máquina.

Este estudio investiga la eliminación reductiva de los complejos dinucleares de paladio (III), revelando que el núcleo dinuclear intacto y la sinergia redox entre los metales impulsan la fácil formación de enlaces C-halógenos.

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Área de la Ciencia:

  • Química organometálica Química orgánica de los metales.
  • La catálisis de la catálisis.
  • Mecanismos de reacción Mecanismos de reacción

Sus antecedentes:

  • En trabajos anteriores se informó de la eliminación reductora de halógenos C de complejos dinucleares Pd (III) en 2009.
  • Los intermediarios dinucleares estuvieron implicados en la oxidación C-H catalizada por Pd(OAc) 2.

Objetivo del estudio:

  • Investigar a fondo el mecanismo de eliminación reductora de los complejos dinucleares Pd (III).
  • Para establecer el papel específico de cada centro metálico de paladio durante la eliminación reductora.

Principales métodos:

  • Investigación experimental de complejos dinucleares de Pd (III).
  • Estudios computacionales teóricos para elucidar las vías de reacción.

Principales resultados:

  • La eliminación reductiva se produce a partir de un complejo donde el núcleo de paladio dinuclear permanece intacto.
  • La evidencia sugiere que la sinergia redox entre los dos metales de paladio facilita la reacción.
  • El mecanismo aclara los roles distintos de cada metal en el proceso de eliminación reductiva.

Conclusiones:

  • Los complejos dinucleares Pd(III) facilitan la eliminación reductora del halógeno C a través de un mecanismo de núcleo intacto.
  • La sinergia redox entre los centros de paladio es crucial para la fácil eliminación reductora observada.
  • Esta comprensión proporciona información clave sobre las reacciones de oxidación catalizadas por el paladio.