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Radical Reactivity: Overview01:11

Radical Reactivity: Overview

2.8K
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...
2.8K
Radical Formation: Addition00:47

Radical Formation: Addition

2.3K
Radicals can be formed by adding a radical to a spin-paired molecule. This is typically observed with unsaturated species, where the addition of a radical across the π bond leads to the production of a new radical by dissolving the π bond. For example, the addition of a Br radical to an alkene yields a carbon-centered radical.
Similar to charge conservation in chemical reactions, spin conservation is implicit for radical reactions. Accordingly, the product formed must possess an...
2.3K
Radical Reactivity: Nucleophilic Radicals01:16

Radical Reactivity: Nucleophilic Radicals

2.7K
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...
2.7K
Radical Reactivity: Steric Effects01:10

Radical Reactivity: Steric Effects

2.5K
The presence of electron-donating, electron-withdrawing, or conjugating groups adjacent to a radical center, imparts electronic stabilization to the radicals. Examples of such electronically-stabilized radicals are triphenylmethyl, tetramethylpiperidine‐N‐oxide, and 2,2‐diphenyl‐1‐picrylhydrazyl. These radicals are remarkably stable and are known as persistent radicals. Some of the persistent radicals can even be isolated and purified.
Along with electronic...
2.5K
Radical Anti-Markovnikov Addition to Alkenes: Overview01:25

Radical Anti-Markovnikov Addition to Alkenes: Overview

4.3K
The addition of hydrogen bromide to alkenes in the presence of hydroperoxides or peroxides proceeds via an anti-Markovnikov pathway and yields alkyl bromides.
4.3K
Radical Reactivity: Concentration Effects01:20

Radical Reactivity: Concentration Effects

1.9K
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...
1.9K

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Related Experiment Video

Updated: Feb 17, 2026

Isolating Free Carbenes, their Mixed Dimers and Organic Radicals
10:44

Isolating Free Carbenes, their Mixed Dimers and Organic Radicals

Published on: April 19, 2019

11.7K

Stable Organic Neutral Diradical via Reversible Coordination.

Zhenpin Lu1, Henrik Quanz1, Olaf Burghaus2

  • 1Institut für Organische Chemie, Justus-Liebig-Universität , Heinrich-Buff-Ring 17, 35392 Giessen, Germany.

Journal of the American Chemical Society
|December 12, 2017
PubMed
Summary
This summary is machine-generated.

Researchers created a stable neutral diboron diradical by coordinating a dinitrogen compound with ortho-phenyldiborane. This reversible process yields a radical species stable above 200 °C, opening new applications.

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Area of Science:

  • Chemistry
  • Materials Science
  • Quantum Chemistry

Background:

  • Stable radicals are crucial for various applications.
  • Generating and controlling radical species remains a significant challenge in chemistry.

Purpose of the Study:

  • To report the formation of a stable neutral diboron diradical.
  • To explore the electronic properties and stability of this novel radical species.
  • To investigate a new method for generating stable radicals.

Main Methods:

  • Coordination chemistry involving an aromatic dinitrogen compound and ortho-phenyldiborane.
  • Reversible reaction demonstrated by the addition of pyridine.
  • Computational studies to analyze the electronic structure and stability of the diradical.

Main Results:

  • Successful formation of a stable neutral diboron diradical.
  • The diradical is stable at temperatures exceeding 200 °C.
  • Reversibility of the formation process confirmed.
  • Computational analysis indicates an open-shell triplet diradical with a small singlet-triplet energy gap, suggesting electronic disjointness.

Conclusions:

  • A novel and stable neutral diboron diradical has been synthesized.
  • This discovery provides a new pathway for generating stable radicals.
  • The unique electronic properties of this diradical offer potential for diverse applications.