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Acid Strength and Molecular Structure03:05

Acid Strength and Molecular Structure

Binary Acids and Bases
In the absence of any leveling effect, the acid strength of binary compounds of hydrogen with nonmetals (A) increases as the H-A bond strength decreases down a group in the periodic table. For group 17, the order of increasing acidity is HF < HCl < HBr < HI. Likewise, for group 16, the order of increasing acid strength is H2O < H2S < H2Se < H2Te. Across a row in the periodic table, the acid strength of binary hydrogen compounds increases with increasing...
Acidity and Basicity of Carboxylic Acid Derivatives01:25

Acidity and Basicity of Carboxylic Acid Derivatives

Carboxylic acids are the strongest among organic acids, as they readily lose the hydroxyl proton to form a resonance-stabilized carboxylate ion. In comparison, the acid derivatives lack acidic hydrogens directly attached to a functional group. In these compounds, the acidic nature arises from their ability to lose α hydrogens, making them weakly acidic.
The relative acidic strength of the derivatives can be explained based on the extent of resonance stabilization of the conjugate base. The...
Acid Halides to Carboxylic Acids: Hydrolysis01:01

Acid Halides to Carboxylic Acids: Hydrolysis

Hydrolysis of acid halides is a nucleophilic acyl substitution reaction in which acid halides react with water to give carboxylic acids. The reaction occurs readily and does not require acid or a base catalyst.
As shown below, the mechanism involves a nucleophilic attack by water at the carbonyl carbon to form a tetrahedral intermediate. This is followed by the reformation of the carbon–oxygen π bond along with the departure of a halide ion. A final proton transfer step yields carboxylic acid...
Acid Halides to Amides: Aminolysis01:07

Acid Halides to Amides: Aminolysis

Aminolysis is a nucleophilic acyl substitution reaction, where ammonia or amines act as nucleophiles to give the substitution product. Acid halides react with ammonia, primary amines, and secondary amines to yield primary, secondary, and tertiary amides, respectively.
In the first step of the aminolysis mechanism, the amine attacks the carbonyl carbon of the acyl chloride to form a tetrahedral intermediate. In the second step, the carbonyl group is re-formed with the elimination of a chloride...
Acid Halides to Ketones: Gilman Reagent01:14

Acid Halides to Ketones: Gilman Reagent

Lithium dialkyl cuprate, also known as Gilman reagents, selectively reduces acid halides to ketones. The acid chloride is treated with Gilman reagent at −78 °C in the presence of ether solution to produce a ketone in good yield.
As shown below, the mechanism proceeds in two steps. First, one of the alkyl groups of the reagent acts as a nucleophile and attacks the acyl carbon of the acid chloride to form a tetrahedral intermediate. This is followed by the reformation of the carbon–oxygen double...
Basicity of Heterocyclic Aromatic Amines01:25

Basicity of Heterocyclic Aromatic Amines

Heterocyclic amines, where the N atom is a part of an alicyclic system, are similar in basicity to alkylamines. Interestingly, the heterocyclic amine having a nitrogen atom as part of an aromatic ring has much less basicity than its corresponding alicyclic counterpart. For this reason, as presented in Figure 1, piperidine (pKb = 2.8) is significantly more basic than pyridine (pKb = 8.8).

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Updated: Jul 4, 2026

Determination of the Gas-phase Acidities of Oligopeptides
11:00

Determination of the Gas-phase Acidities of Oligopeptides

Published on: June 24, 2013

Práctica aziridinación de olefinas con un amplio alcance de sustrato.

Tung Siu1, Andrei K Yudin

  • 1Department of Chemistry, University of Toronto, 80 St. George St., Toronto, Ontario, Canada M5S 3H6.

Journal of the American Chemical Society
|January 24, 2002
PubMed
Resumen
Este resumen es generado por máquina.

Este estudio presenta un método electroquímico para reacciones redox orgánicas, evitando reactivos tóxicos. Convierte eficientemente las olefinas en aziridinas utilizando N-aminoftalimida y potenciales electroquímicos selectivos.

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Área de la Ciencia:

  • Electroquímica orgánica y orgánica.
  • Química verde es la química verde.
  • Química orgánica sintética y orgánica.

Sus antecedentes:

  • Las reacciones redox orgánicas tradicionales a menudo se basan en cantidades estequiométricas de oxidantes tóxicos y aditivos metálicos.
  • Estos reactivos plantean preocupaciones ambientales y de seguridad, lo que hace necesario el desarrollo de metodologías sintéticas más limpias.
  • La funcionalización selectiva de las olefinas puede ser un desafío, especialmente cuando se trata de sustratos que poseen potenciales redox similares.

Objetivo del estudio:

  • Desarrollar un enfoque racional y ambientalmente benigno para las reacciones redox orgánicas.
  • Para demostrar un proceso de aziridinación eficiente utilizando la electroquímica.
  • Para lograr la transformación selectiva del sustrato aprovechando el control del potencial electroquímico.

Principales métodos:

  • Síntesis electroquímica que utiliza una N-aminoftalimida fácilmente disponible como fuente de nitrógeno.
  • Aplicación de un continuo de potenciales aplicados para impulsar las reacciones redox.
  • Explotación de las condiciones de reacción heterogéneas en las superficies de los electrodos para controlar la selectividad.

Principales resultados:

  • Aziridinación exitosa de las olefinas ricas en electrones y pobres en electrones con alta eficiencia.
  • Demostración de la discriminación electroquímica entre sustratos con potenciales redox similares.
  • Atribución de la selectividad al fenómeno de sobrepotencial e inhibición cinética de la transferencia de electrones.

Conclusiones:

  • Los métodos electroquímicos ofrecen una alternativa sostenible a las reacciones redox orgánicas tradicionales, eliminando la necesidad de reactivos tóxicos.
  • El proceso de aziridinación descrito es eficiente y versátil, aplicable a una amplia gama de sustratos de olefinas.
  • El control electroquímico sobre la selectividad de la reacción proporciona una herramienta poderosa para la síntesis orgánica compleja.