СВЯЖИТЕСЬ С НАМИ

Войдите в систему

15.11 : α-Bromination of Carboxylic Acids: Hell–Volhard–Zelinski Reaction

Hell–Volhard–Zelinsky reaction is a method to convert carboxylic acids bearing α hydrogen to α-brominated carboxylic acids in the presence of a mixture of phosphorus tribromide and bromine, followed by hydrolysis.

Phosphorus tribromide acts as a catalyst—it is either added directly or generated in situ by the reaction of red phosphorus with bromine.

The reaction begins with the carboxylic acid and the catalyst interacting to generate the acid bromide and HBr.

HBr then catalyzes the enolization of acid bromide to its enol form, both of which exist in equilibrium.

The enol form acts as a nucleophile that undergoes an α substitution reaction with bromine to form an α-bromo acid bromide.

This active intermediate, upon treatment with water, undergoes hydrolysis to produce the desired α-brominated acid.

If instead of water, alcohols or amines are used, the intermediate is converted to its respective α-brominated acid derivative.

The method to achieve α-brominated carboxylic acids using a mixture of phosphorus tribromide and bromine is known as the Hell–Volhard–Zelinski reaction. The reaction is catalyzed by phosphorus tribromide, which can be used directly or produced in situ from red phosphorus and bromine. The mechanism comprises PBr₃ catalyzed conversion of acid to acid bromide and hydrogen bromide. The acid bromide enolizes to its enol form in the presence of HBr. The nucleophilic enol attacks the bromine molecule to give an α-bromo acid bromide. The resulting molecule, upon subsequent hydrolysis, yields the desired α-bromo acid.

Теги

bromination Carboxylic Acids Hell Volhard Zelinski Reaction Phosphorus Tribromide Bromine Acid Bromide Enol Nucleophilic Addition Hydrolysis

Из главы 15:

article

Now Playing

15.11 : α-Bromination of Carboxylic Acids: Hell–Volhard–Zelinski Reaction

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.9K Просмотры

article

15.1 : Реакционная способность энолов

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.9K Просмотры

article

15.2 : Реакционная способность ионов енолирования

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.4K Просмотры

article

15.3 : Виды энолов и энолатов

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.5K Просмотры

article

15.4 : Конвенции механизма Enolate

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.0K Просмотры

article

15.5 : Региоселективное образование энолатов

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.5K Просмотры

article

15.6 : Стереохимические эффекты энолизации

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.0K Просмотры

article

15.7 : Катализируемое кислотой α-галогенирование альдегидов и кетонов

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.5K Просмотры

article

15.8 : Стимулируемое основаниями α-галогенирование альдегидов и кетонов

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.3K Просмотры

article

15.9 : Многократное галогенирование метилкетонов: галоформная реакция

α-Carbon Chemistry: Enols, Enolates, and Enamines

1.9K Просмотры

article

15.10 : α-Галогенирование производных карбоновой кислоты: обзор

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.2K Просмотры

article

15.12 : Реакции α-галокарбонильных соединений: нуклеофильное замещение

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.2K Просмотры

article

15.13 : Нитрозирование энолов

α-Carbon Chemistry: Enols, Enolates, and Enamines

2.4K Просмотры

article

15.14 : Образование C–C связей: обзор конденсации альдола

α-Carbon Chemistry: Enols, Enolates, and Enamines

13.4K Просмотры

article

15.15 : Катализируемая основаниями реакция добавления алдола

α-Carbon Chemistry: Enols, Enolates, and Enamines

3.1K Просмотры

See More

Конфиденциальность

Условия эксплуатации

Политика

СВЯЖИТЕСЬ С НАМИ

РЕКОМЕНДОВАТЬ БИБЛИОТЕКЕ

НОВОСТИ JoVE

Исследования

Образование

АВТОРЫ

Библиотекарь

О JoVE

Авторские права © 2025 MyJoVE Corporation. Все права защищены