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Related Concept Videos

Base-Catalyzed Aldol Addition Reaction01:08

Base-Catalyzed Aldol Addition Reaction

3.8K
As depicted in Figure 1, base-catalyzed aldol addition involves adding two carbonyl compounds in aqueous sodium hydroxide to form a β-hydroxy carbonyl compound.
3.8K
Acid-Catalyzed α-Halogenation of Aldehydes and Ketones01:21

Acid-Catalyzed α-Halogenation of Aldehydes and Ketones

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By replacing an α-hydrogen with a halogen, acid-catalyzed α-halogenation of aldehydes or ketones yields a monohalogenated product
In the first step of the mechanism, the acid protonates the carbonyl oxygen resulting in a resonance-stabilized cation, which subsequently loses an α-hydrogen to form an enol tautomer. The C=C bond in an enol is highly nucleophilic because of the electron-donating nature of the –OH group. Consequently, the double bond attacks an electrophilic halogen to form a...
4.1K
Base-Promoted α-Halogenation of Aldehydes and Ketones00:51

Base-Promoted α-Halogenation of Aldehydes and Ketones

3.7K
α-Halogenation of aldehydes and ketones is a reaction involving the substitution of α hydrogens with halogens in the presence of a base.  The reaction begins with the abstraction of  α hydrogen by the base to produce a nucleophilic enolate ion. This intermediate undergoes a subsequent nucleophilic substitution with the halogen to produce a monohalogenated carbonyl compound. If the starting substrate has more than one α hydrogen, it is difficult to stop the reaction...
3.7K
Crossed Aldol Reactions: Overview01:04

Crossed Aldol Reactions: Overview

5.6K
Crossed aldol addition is the reaction between two different carbonyl compounds under acidic or basic conditions. Here, both the carbonyl compounds function as nucleophiles and electrophiles. As shown in Figure 1, such a reaction yields a mixture of products, two of which are formed via self-condensation, while the remaining two are formed via crossed-condensation. Without adjustment, the reaction's usefulness in organic chemistry is decreased.
5.6K
Crossed Aldol Reaction Using Strong Bases: Directed Aldol Reaction00:56

Crossed Aldol Reaction Using Strong Bases: Directed Aldol Reaction

2.3K
The reaction between two different carbonyl compounds comprising α hydrogen in the presence of a strong base like lithium diisopropylamide (LDA) to form a crossed aldol product is known as a directed aldol reaction. The directed aldol reaction is depicted in Figure 1.
2.3K
Acid-Catalyzed Aldol Addition Reaction01:15

Acid-Catalyzed Aldol Addition Reaction

2.8K
The aldol reaction of a ketone under acidic conditions successfully forms an unsaturated carbonyl as the final product instead of an aldol. The acid-catalyzed aldol reaction is depicted in Figure 1.
2.8K

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Related Experiment Video

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Facile Preparation of 2Z,4E-Dienamides by the Olefination of Electron-deficient Alkenes with Allyl Acetate
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Copper-Catalyzed Aldehyde Exchanged Amidation.

Lei-Yang Zhang1, Nai-Xing Wang1, Yue-Hua Wu1

  • 1Technical Institute of Physics and Chemistry & University of Chinese Academy of Sciences, Chinese Academy of Sciences, Beijing 100190, China.

Organic Letters
|December 30, 2021
PubMed
Summary
This summary is machine-generated.

Chemists synthesized novel secondary amides with aldehyde groups from various aldehydes and amines. This efficient method, yielding up to 89%, offers a new route to valuable chemical compounds.

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Area of Science:

  • Organic Chemistry
  • Synthetic Chemistry
  • Catalysis

Background:

  • The synthesis of bioactive amides is a significant area of chemical research.
  • Developing efficient methods for incorporating functional groups into amides is crucial for creating new molecules.

Purpose of the Study:

  • To report the first synthesis of secondary amides bearing an aldehyde group.
  • To establish a versatile and efficient method for generating these novel amide compounds.

Main Methods:

  • Reaction of various (hetero)aryl and aliphatic aldehydes with secondary amines.
  • Utilized a Copper (Cu) catalytic system (Cu(I/II/III) cycle).
  • Employed high-resolution mass spectrometry to detect key reaction intermediates.

Main Results:

  • Successfully synthesized secondary amides containing an aldehyde group from over 40 examples of aldehydes.
  • Achieved moderate to excellent product yields, up to 89%.
  • Proposed and provided evidence for a reaction mechanism involving a Cu(I/II/III) catalytic cycle and radical rearrangement.

Conclusions:

  • A novel and efficient synthetic route to secondary amides with aldehyde functionalities has been developed.
  • The proposed catalytic cycle and radical rearrangement mechanism provide insight into the reaction pathway.
  • This method offers a valuable tool for accessing diverse amide-containing molecules for further chemical applications.