Issue 15, 2024

Photochemical formation of the elusive Dewar isomers of aromatic systems: why are substituted azaborines different?

Abstract

Photochemical reactions enabling efficient transformation of aromatic systems into energetic but stable non-aromatic isomers have a long history in organic chemistry. One recently discovered reaction in this realm is that where derivatives of 1,2-azaborine, a compound isoelectronic with benzene in which two adjacent C atoms are replaced by B and N atoms, form the non-hexagon Dewar isomer. Here, we report quantum-chemical calculations that explain both why 1,2-azaborine is intrinsically more reactive toward Dewar formation than benzene, and how suitable substitutions at the B and N atoms are able to increase the corresponding quantum yield. We find that Dewar formation from 1,2-azaborine is favored by a pronounced driving force that benzene lacks, and that a large improvement in quantum yield arises when the reaction of substituted 1,2-azaborines proceeds without involvement of an intermediary ground-state species. Overall, we report new insights into making photochemical use of the Dewar isomers of aromatic compounds.

Graphical abstract: Photochemical formation of the elusive Dewar isomers of aromatic systems: why are substituted azaborines different?

Supplementary files

Article information

Article type
Paper
Submitted
22 Feb 2024
Accepted
19 Mar 2024
First published
19 Mar 2024
This article is Open Access
Creative Commons BY license

Phys. Chem. Chem. Phys., 2024,26, 11295-11305

Photochemical formation of the elusive Dewar isomers of aromatic systems: why are substituted azaborines different?

E. M. Arpa, S. Stafström and B. Durbeej, Phys. Chem. Chem. Phys., 2024, 26, 11295 DOI: 10.1039/D4CP00777H

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