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Radical Substitution: Allylic Chlorination01:31

Radical Substitution: Allylic Chlorination

3.4K
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...
3.4K
Radical Reactivity: Electrophilic Radicals01:02

Radical Reactivity: Electrophilic Radicals

2.6K
Radicals adjacent to electron‐withdrawing groups are called electrophilic radicals. These radicals readily react with nucleophilic alkenes. For example, the malonate radical, in which the radical center is flanked by two electron‐withdrawing groups, reacts readily with butyl vinyl ether, which consists of an electron‐donating oxygen substituent. The reaction between electrophilic malonate radical and nucleophilic vinyl ether is favored because the radical has a...
2.6K
Radical Substitution: Halogenation of Alkanes and Alkyl Substituents01:27

Radical Substitution: Halogenation of Alkanes and Alkyl Substituents

10.5K
In the presence of heat or light, alkanes react with molecular halogens to form alkyl halides by a substitution reaction called radical halogenation. This reaction has three steps: initiation, propagation, and termination, as seen in the radical chlorination of methane to produce methyl chloride.
In the initiation step of the reaction, the chlorine molecule undergoes homolytic cleavage in the presence of light or heat, forming two highly reactive chlorine radicals. Propagation occurs in two...
10.5K
Radical Reactivity: Nucleophilic Radicals01:16

Radical Reactivity: Nucleophilic Radicals

2.8K
Radicals adjacent to electron-donating groups are called nucleophilic radicals. These radicals readily react with electrophilic alkenes. The SOMO–LUMO interactions are the driving force for the reaction, where the high-energy SOMO of the electron-rich, nucleophilic radicals interacts with the low-energy LUMO of the electron-deficient, electrophilic alkenes. Such SOMO–LUMO interactions are the basis of reactive radical traps, affecting the selectivity in radical reactions. For...
2.8K
Radical Reactivity: Overview01:11

Radical Reactivity: Overview

3.0K
Radicals, the highly reactive species, gain stability by undergoing three different reactions. The first reaction involves a radical-radical coupling, in which a radical combines with another radical, forming a spin‐paired molecule. The second reaction is between a radical and a spin‐paired molecule, generating a new radical and a new spin‐paired molecule. The third reaction is radical decomposition in a unimolecular reaction, forming a new radical and a spin‐paired...
3.0K
Radical Substitution: Allylic Bromination01:27

Radical Substitution: Allylic Bromination

6.9K
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...
6.9K

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Related Experiment Video

Updated: Mar 31, 2026

Protocol for the Synthesis of Ortho-trifluoromethoxylated Aniline Derivatives
08:43

Protocol for the Synthesis of Ortho-trifluoromethoxylated Aniline Derivatives

Published on: January 19, 2016

11.0K

Radical-Mediated Fluoroalkylations.

Eun Jin Cho1

  • 1Department of Chemistry, Chung-Ang University, 84 Heukseok-ro, Dongjak-gu, Seoul, 156-756, Republic of Korea.

Chemical Record (New York, N.Y.)
|October 27, 2015
PubMed
Summary

Eco-friendly radical fluoroalkylation reactions using visible-light photocatalysis and inorganic electrides offer sustainable synthetic routes. These methods enable the introduction of fluoroalkyl groups, impacting pharmaceuticals, agrochemicals, and materials science.

Keywords:
fluoroalkylationinorganic electridesphotocatalysisradical reactionsvisible light

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Application of Elemental Lanthanides in the Selective C-F Activation of Trifluoromethylated Benzofulvenes Providing Access to Various Difluoroalkenes
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Application of Elemental Lanthanides in the Selective C-F Activation of Trifluoromethylated Benzofulvenes Providing Access to Various Difluoroalkenes

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Atom Transfer Radical Polymerization of Functionalized Vinyl Monomers Using Perylene as a Visible Light Photocatalyst
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Application of Elemental Lanthanides in the Selective C-F Activation of Trifluoromethylated Benzofulvenes Providing Access to Various Difluoroalkenes
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Atom Transfer Radical Polymerization of Functionalized Vinyl Monomers Using Perylene as a Visible Light Photocatalyst
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Atom Transfer Radical Polymerization of Functionalized Vinyl Monomers Using Perylene as a Visible Light Photocatalyst

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Area of Science:

  • Synthetic Chemistry
  • Green Chemistry

Background:

  • Visible-light photocatalysis is a versatile and environmentally compatible method for chemical synthesis.
  • Inorganic electrides, derived from abundant metals like calcium, serve as effective and eco-friendly electron donors for radical reactions.

Purpose of the Study:

  • To review recent advancements in radical-mediated fluoroalkylation reactions.
  • To highlight the use of visible-light photocatalysis and inorganic electrides in these transformations.
  • To discuss the impact of fluoroalkylation on pharmaceuticals, agrochemicals, and material sciences.

Main Methods:

  • Radical-mediated fluoroalkylation reactions.
  • Visible-light photocatalysis.
  • Utilizing inorganic electrides as electron donors.

Main Results:

  • Development of novel fluoroalkylation reactions, including trifluoromethylation and difluoroalkylation.
  • Demonstration of eco-friendly and efficient synthetic pathways.
  • Successful introduction of fluoroalkyl groups into organic compounds.

Conclusions:

  • Visible-light photocatalysis combined with inorganic electrides provides a powerful platform for sustainable fluoroalkylation.
  • These methods have significant potential to advance drug discovery, crop protection, and materials development.