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Radical Substitution: Allylic Bromination01:27

Radical Substitution: Allylic Bromination

5.3K
In organic synthesis, the formation of products can be altered by changing the reaction conditions. For example, a dibromo addition product is formed when propene is treated with bromine at room temperature. In contrast, propene undergoes allylic substitution in non-polar solvents at high temperatures to give 3-bromopropene. In order to avoid the addition reaction, the bromine concentration must be kept as low as possible throughout the reaction. This can be achieved using N-bromosuccinimide...
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Radical Substitution: Allylic Chlorination01:31

Radical Substitution: Allylic Chlorination

2.4K
Typically, when alkenes react with halogens at low temperatures, an addition reaction occurs. However, upon increasing the temperature or under reaction conditions that form radicals, providing a low but steady concentration of halogen radicals, allylic substitution reaction is favored. This is because allylic hydrogens are very reactive as the formed intermediate is resonance stabilized. For example, when propene is treated with chlorine in the gas phase at 400 °C, it undergoes allylic...
2.4K
Radical Anti-Markovnikov Addition to Alkenes: Overview01:25

Radical Anti-Markovnikov Addition to Alkenes: Overview

3.6K
The addition of hydrogen bromide to alkenes in the presence of hydroperoxides or peroxides proceeds via an anti-Markovnikov pathway and yields alkyl bromides.
3.6K
Radical Halogenation: Stereochemistry01:33

Radical Halogenation: Stereochemistry

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Stereochemistry is the study of the different spatial arrangements of atoms in a given molecule. The stereochemistry of radical halogenations can be understood from three different situations:
Halogenation to form a new chiral center:
3.9K
Radical Reactivity: Concentration Effects01:20

Radical Reactivity: Concentration Effects

1.5K
In a radical reaction, the concentration of starting materials governs the selectivity of a radical. For example, the reaction between an alkyl halide and an alkene, in the presence of tin hydride and AIBN, begins with the generation of a tin radical. The generated radical then abstracts halogen from the alkyl halide, producing an alkyl radical. This alkyl radical can either react with tin hydride, yielding an alkane, or add to an alkene, generating a nitrile-stabilized radical, eventually...
1.5K
Radical Anti-Markovnikov Addition to Alkenes: Mechanism01:17

Radical Anti-Markovnikov Addition to Alkenes: Mechanism

4.0K
The reaction of hydrogen bromide with alkenes in the presence of hydroperoxides or peroxides proceeds via anti-Markovnikov addition. The radical chain reaction comprises initiation, propagation, and termination steps.
The mechanism starts with chain initiation, which involves two steps. In the first chain initiation step, a weak peroxide bond is homolytically cleaved upon mild heating to form two alkoxy radicals. In the second initiation step, a hydrogen atom is abstracted by the alkoxy...
4.0K

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Updated: Sep 1, 2025

Facile Preparation of 2Z,4E-Dienamides by the Olefination of Electron-deficient Alkenes with Allyl Acetate
06:46

Facile Preparation of 2Z,4E-Dienamides by the Olefination of Electron-deficient Alkenes with Allyl Acetate

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Radical transformations for allene synthesis.

Yajun Li1,2, Hongli Bao1,3

  • 1Key Laboratory of Coal to Ethylene Glycol and Its Related Technology, Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences Fuzhou 350002 P. R. of China hlbao@fjirsm.ac.cn.

Chemical Science
|August 17, 2022
PubMed
Summary
This summary is machine-generated.

This review highlights recent advances in synthesizing allenes, which are crucial organic molecules, using radical intermediates. It categorizes methods by substrate and catalyst, discussing mechanisms and challenges.

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Area of Science:

  • Organic Chemistry
  • Synthetic Chemistry

Background:

  • Allenes are versatile organic molecules with unique properties.
  • They are important building blocks for natural products, pharmaceuticals, and functional materials.
  • Established methodologies exist for allene synthesis, with recent focus on radical approaches.

Purpose of the Study:

  • To provide a perspective on recent advances in the synthesis of allenes via radical intermediates.
  • To categorize these synthetic methods based on substrate types and catalytic systems.
  • To highlight mechanistic studies and synthetic challenges in radical allene synthesis.

Main Methods:

  • Review of recent literature on radical synthesis of allenes.
  • Categorization of methods by substrate class (e.g., alkynes, alkenes, etc.).
  • Classification of methods based on distinct catalytic systems (e.g., transition metal catalysis, photoredox catalysis).

Main Results:

  • Compilation of diverse radical-mediated strategies for allene synthesis.
  • Discussion of the scope and limitations of various synthetic approaches.
  • Analysis of mechanistic pathways involved in radical allene formation.

Conclusions:

  • Radical synthesis offers powerful and versatile routes to allenes.
  • Continued research is needed to address synthetic challenges and expand methodologies.
  • Allenes synthesized via radical pathways hold significant potential in various chemical applications.