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Oxidation of Phenols to Quinones01:17

Oxidation of Phenols to Quinones

In the presence of oxidizing agents, phenols are oxidized to quinones. Quinones can be easily reduced back to phenols using mild reducing agents. The electron-donating hydroxyl group enhances the reactivity of the aromatic ring, enabling oxidation of the ring even in the absence of an α hydrogen.
o-hydroxy phenols are oxidized to o-quinones and p-hydroxy phenols to p-quinones. Such redox reactions involve the transfer of two electrons and two protons. The reversible redox property is crucial in...
Structure and Nomenclature of Alcohols and Phenols02:23

Structure and Nomenclature of Alcohols and Phenols

Overview
Alcohols are one of the most important functional groups in organic chemistry. The name of alcohol comes from the hydrocarbon from which it is derived. Alcohols are organic molecules containing the functional hydroxyl or –OH group directly bonded to carbon. Phenols have an OH group directly attached to a benzene ring. While alcohols are colorless, phenol is a white crystalline compound with a characteristic "hospital smell" odor.
As with other organic compounds, alcohols and phenols...
Acidity and Basicity of Alcohols and Phenols02:36

Acidity and Basicity of Alcohols and Phenols

Like water, alcohols are weak acids and bases. This is attributed to the polarization of the O–H bond making the hydrogen partially positive. Moreover, the electron pairs on the oxygen atom of alcohol make it both basic and nucleophilic. Protonation of an alcohol converts hydroxide, a poor leaving group, into water—a good one. The two acid–base equilibria corresponding to ethanol are depicted below.
Structure and Nomenclature of Epoxides02:38

Structure and Nomenclature of Epoxides

Cyclic ethers are heterocyclic compounds with an oxygen atom in the ring along with carbon atoms. They are named depending on the number of carbon atoms present in their ring system. Cyclic ethers with a three-membered ring system are called “oxirane”, four-membered ring systems as “oxetane”, five-membered ring systems as “oxolane”, and six-membered ring systems as “oxane”. The cyclic structure of these rings imposes angle strain, and this strain is more in the ring having a smaller number of...
Phase II Reactions: Methylation Reactions01:17

Phase II Reactions: Methylation Reactions

Methylation is a phase II biotransformation process involving the attachment of a methyl group to a substrate. Enzymes known as methyltransferases orchestrate this reaction.
The mechanism of methylation unfolds in two stages. The first stage sees a methyltransferase enzyme facilitating the transfer of a methyl group from S-adenosylmethionine (SAM) to the substrate, forming S-adenosylhomocysteine (SAH). The second stage involves further metabolism of SAH into homocysteine, which can be recycled...
Radical Chain-Growth Polymerization: Overview01:10

Radical Chain-Growth Polymerization: Overview

Chain-growth or addition polymerization is successive addition reactions of monomers with a polymer chain. In radical chain-growth polymerization, the reaction proceeds via a free-radical intermediate. The free radical is formed from radical initiators, which spontaneously generate free radicals by homolytic fission. Organic peroxides (such as dibenzoyl peroxide, as shown in Figure 1) or azo compounds are popular radical initiators. A low concentration ratio of radical initiator to monomer is...

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Related Experiment Video

Updated: Jun 1, 2026

Facile Preparation of 4-Substituted Quinazoline Derivatives
11:51

Facile Preparation of 4-Substituted Quinazoline Derivatives

Published on: February 15, 2016

8-Meth-oxy-4-(4-methoxy-phen-yl)quinoline.

Ligia Llovera, Teresa González, Pavel Anzenbacher

    Acta Crystallographica. Section E, Structure Reports Online
    |May 18, 2011
    PubMed
    Summary

    This study details the crystal structure of a novel organic compound, C(17)H(15)NO(2). The research highlights the molecular geometry and intermolecular interactions, specifically hydrogen bonds and C-H⋯π interactions, within its crystalline form.

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    Green Synthesis of Quinoline-Based Ionic Liquid
    05:59

    Green Synthesis of Quinoline-Based Ionic Liquid

    Published on: September 27, 2024

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    Last Updated: Jun 1, 2026

    Facile Preparation of 4-Substituted Quinazoline Derivatives
    11:51

    Facile Preparation of 4-Substituted Quinazoline Derivatives

    Published on: February 15, 2016

    Green Synthesis of Quinoline-Based Ionic Liquid
    05:59

    Green Synthesis of Quinoline-Based Ionic Liquid

    Published on: September 27, 2024

    Area of Science:

    • Crystallography
    • Organic Chemistry
    • Supramolecular Chemistry

    Background:

    • Understanding the three-dimensional arrangement of atoms in organic molecules is crucial.
    • Intermolecular forces dictate crystal packing and material properties.

    Purpose of the Study:

    • To elucidate the crystal structure of the compound C(17)H(15)NO(2).
    • To analyze the dihedral angle between the quinoline and benzene ring systems.
    • To identify and describe the intermolecular interactions present in the crystal.

    Main Methods:

    • Single-crystal X-ray diffraction was employed to determine the molecular and crystal structure.
    • Analysis of bond lengths, bond angles, and dihedral angles was performed.
    • Intermolecular interactions, including hydrogen bonds and C-H⋯π interactions, were identified.

    Main Results:

    • The crystal structure of C(17)H(15)NO(2) was successfully determined.
    • A significant dihedral angle of 62.17(1)° was observed between the quinoline and benzene rings.
    • Zigzag chains were formed via C-H⋯O hydrogen bonds, further linked by C-H⋯π interactions.

    Conclusions:

    • The study provides detailed structural information for C(17)H(15)NO(2).
    • The observed dihedral angle influences the molecule's conformation.
    • The identified hydrogen bonds and C-H⋯π interactions are key to the crystal's supramolecular architecture.