The Reaction Mechanism Between Tetraarylammonium Salts and Hydroxide

Nansi Gjineci; Sinai Aharonovich; Sapir Willdorf-Cohen; Dario R. Dekel; Charles E. Diesendruck

doi:10.1002/ejoc.202000435

The Reaction Mechanism Between Tetraarylammonium Salts and Hydroxide

Nansi Gjineci, Sinai Aharonovich, Sapir Willdorf-Cohen, Dario R. Dekel, Charles E. Diesendruck

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

The mechanism of the reaction between tetraaryl ammonium salts and hydroxide is studied experimentally for different N,N-diaryl carbazolium salts. The N,N-diarylcarbazolium salts are designed, synthesized, characterized, and reacted with hydroxide under different conditions. The products of the reactions were directly characterized or isolated when possible and, using different substituents, the reaction mechanisms were compared. An unexpected H/D exchange observed in these salts helped to discard the classical S_NAr mechanisms, supporting instead a radical mechanism initiated by a single-electron transfer from the hydroxide. By understanding the preferred reaction pathways, better quaternary ammonium salts can be designed to withstand aggressive alkaline environments, critical for many practical applications such as anion-exchange membrane fuel cells.

Original language	American English
Pages (from-to)	3161-3168
Number of pages	8
Journal	European Journal of Organic Chemistry
Volume	2020
Issue number	21
DOIs	https://doi.org/10.1002/ejoc.202000435
State	Published - 8 Jun 2020

Keywords

Ammonium salts
Nucleophilic substitution
Reaction mechanisms
Single electron transfer

All Science Journal Classification (ASJC) codes

Physical and Theoretical Chemistry
Organic Chemistry

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/ejoc.202000435

Cite this

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title = "The Reaction Mechanism Between Tetraarylammonium Salts and Hydroxide",

abstract = "The mechanism of the reaction between tetraaryl ammonium salts and hydroxide is studied experimentally for different N,N-diaryl carbazolium salts. The N,N-diarylcarbazolium salts are designed, synthesized, characterized, and reacted with hydroxide under different conditions. The products of the reactions were directly characterized or isolated when possible and, using different substituents, the reaction mechanisms were compared. An unexpected H/D exchange observed in these salts helped to discard the classical SNAr mechanisms, supporting instead a radical mechanism initiated by a single-electron transfer from the hydroxide. By understanding the preferred reaction pathways, better quaternary ammonium salts can be designed to withstand aggressive alkaline environments, critical for many practical applications such as anion-exchange membrane fuel cells.",

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doi = "10.1002/ejoc.202000435",

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AU - Gjineci, Nansi

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AU - Willdorf-Cohen, Sapir

AU - Dekel, Dario R.

AU - Diesendruck, Charles E.

PY - 2020/6/8

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N2 - The mechanism of the reaction between tetraaryl ammonium salts and hydroxide is studied experimentally for different N,N-diaryl carbazolium salts. The N,N-diarylcarbazolium salts are designed, synthesized, characterized, and reacted with hydroxide under different conditions. The products of the reactions were directly characterized or isolated when possible and, using different substituents, the reaction mechanisms were compared. An unexpected H/D exchange observed in these salts helped to discard the classical SNAr mechanisms, supporting instead a radical mechanism initiated by a single-electron transfer from the hydroxide. By understanding the preferred reaction pathways, better quaternary ammonium salts can be designed to withstand aggressive alkaline environments, critical for many practical applications such as anion-exchange membrane fuel cells.

AB - The mechanism of the reaction between tetraaryl ammonium salts and hydroxide is studied experimentally for different N,N-diaryl carbazolium salts. The N,N-diarylcarbazolium salts are designed, synthesized, characterized, and reacted with hydroxide under different conditions. The products of the reactions were directly characterized or isolated when possible and, using different substituents, the reaction mechanisms were compared. An unexpected H/D exchange observed in these salts helped to discard the classical SNAr mechanisms, supporting instead a radical mechanism initiated by a single-electron transfer from the hydroxide. By understanding the preferred reaction pathways, better quaternary ammonium salts can be designed to withstand aggressive alkaline environments, critical for many practical applications such as anion-exchange membrane fuel cells.

KW - Ammonium salts

KW - Nucleophilic substitution

KW - Reaction mechanisms

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The Reaction Mechanism Between Tetraarylammonium Salts and Hydroxide

Abstract

Keywords

All Science Journal Classification (ASJC) codes

UN SDGs

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