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Radical Reactivity: Electrophilic Radicals01:02

Radical Reactivity: Electrophilic Radicals

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 low‐energy SOMO, which interacts...
Radical Reactivity: Nucleophilic Radicals01:16

Radical Reactivity: Nucleophilic Radicals

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 instance, consider...
Diazonium Group Substitution: –OH and –H01:19

Diazonium Group Substitution: –OH and –H

Nitrous acid, a weak acid, is prepared in situ via the reaction of sodium nitrite with a strong acid under cold conditions. This nitrous acid prepared in situ reacts with primary arylamines to form arenediazonium salts. Such reactions are known as diazotization reactions. As shown in Figure 1, the formation of arenediazonium salts begins with the decomposition of nitrous acid in an acidic solution to give nitrosonium ions.
Oxidation of Alkenes: Anti Dihydroxylation with Peroxy Acids02:04

Oxidation of Alkenes: Anti Dihydroxylation with Peroxy Acids

Diols are compounds with two hydroxyl groups. In addition to syn dihydroxylation, diols can also be synthesized through the process of anti dihydroxylation. The process involves treating an alkene with a peroxycarboxylic acid to form an epoxide. Epoxides are highly strained three-membered rings with oxygen and two carbons occupying the corners of an equilateral triangle. This step is followed by ring-opening of the epoxide in the presence of an aqueous acid to give a trans diol.
Oxidation of Alkenes: Syn Dihydroxylation with Osmium Tetraoxide02:44

Oxidation of Alkenes: Syn Dihydroxylation with Osmium Tetraoxide

Alkenes are converted to 1,2-diols or glycols through a process called dihydroxylation. It involves the addition of two hydroxyl groups across the double bond with two different stereochemical approaches, namely anti and syn. Dihydroxylation using osmium tetroxide progresses with syn stereochemistry.
Radical Anti-Markovnikov Addition to Alkenes: Overview01:25

Radical Anti-Markovnikov Addition to Alkenes: Overview

The addition of hydrogen bromide to alkenes in the presence of hydroperoxides or peroxides proceeds via an anti-Markovnikov pathway and yields alkyl bromides.

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Video Experimental Relacionado

Updated: Jul 12, 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

Reactividad del radical hidroxilo con la dietilhidroxilamina.

R A Gorse, R R Lii, B B Saunders

    Science (New York, N.Y.)
    |September 30, 1977
    PubMed
    Resumen

    La dietilhidroxilamina (DEHA) reacciona rápidamente con los radicales hidroxilo de la fase gaseosa, a diferencia de su reacción más lenta en el agua. Esta alta reactividad sugiere que el DEHA puede inhibir la formación de smog atmosférico.

    Área de la Ciencia:

    • Química de la atmósfera química de la atmósfera
    • La cinética química es la cinética química.
    • Ciencias ambientales Ciencias ambientales.

    Sus antecedentes:

    • La dietilhidroxilamina (DEHA) es un compuesto químico con aplicaciones potenciales en procesos atmosféricos.
    • Comprender la cinética de reacción del DEHA es crucial para predecir su impacto ambiental.
    • Los radicales hidroxilo son oxidantes clave en la atmósfera y juegan un papel importante en la formación de smog.

    Objetivo del estudio:

    • Investigar la velocidad de reacción del DEHA con radicales hidroxilo tanto en la fase gaseosa como en la fase acuosa.
    • Determinar las implicaciones de la reactividad del DEHA para la formación de smog atmosférico.
    • Para dilucidar el mecanismo de reacción del DEHA con los radicales hidroxilo en solución acuosa.

    Principales métodos:

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    • Se llevaron a cabo estudios experimentales para medir las tasas de reacción.
    • Las reacciones en fase gaseosa y en fase acuosa se analizaron por separado.
    • Se recogieron y analizaron datos cinéticos para comprender las vías de reacción.

    Principales resultados:

    • El DEHA exhibe una alta tasa de reacción con los radicales hidroxilo de la fase gaseosa, que ocurre en aproximadamente cada tercera colisión.
    • La reacción del DEHA con los radicales hidroxilo en solución acuosa es significativamente más lenta en comparación con la reacción en fase gaseosa.
    • La reactividad de la fase gaseosa observada apoya la predicción del efecto inhibidor del DEHA sobre el smog atmosférico.

    Conclusiones:

    • La rápida reacción en fase gaseosa del DEHA con los radicales hidroxilo es un factor clave en su potencial papel como inhibidor del smog atmosférico.
    • Otros estudios sobre el mecanismo de reacción de la fase acuosa del DEHA con los radicales hidroxilo son valiosos para una comprensión completa.
    • La reactividad diferencial de DEHA en las fases gaseosa y acuosa tiene importantes implicaciones para la química ambiental y el control de la contaminación.