Issue 8, 2021

Visible light photoredox by a (ph,ArNacNac)2Zn photocatalyst: photophysical properties and mechanistic understanding

Abstract

A class of potent zinc-based photocatalysts have been developed in this report, whose reducing properties are dependent on the ligand redox of the beta-diketiminate backbone. Two molecules have been crystallographically characterized to reveal that zinc is trapped in a tetrahedral environment posed by two beta-diketiminate backbones. Upon excitation with blue light, the molecules generate a relatively long-lived excited state in the range of ∼12 nanoseconds as determined by a time-correlated single photon counting experiment. The long-lived excited state is reductively quenched by an amine and the reduction is a ligand-based process. Stern–Volmer quenching kinetics was performed to find a linear correlation of the reduced fluorescence intensity with increasing quencher concentration that suggests a dynamic quenching process. Under photochemical conditions, the radical anion of the zinc complex transfers a single electron to break a C–Br bond and conducts atom transfer radical addition (ATRA) type reactions. Leveraging on the single electron transfer from the reduced backbone further, a Meerwein arylation reaction has also been developed. A plausible mechanistic pathway has been delineated for ATRA reactions, depending on the gathered evidence and appropriate intermediate isolation.

Graphical abstract: Visible light photoredox by a (ph,ArNacNac)2Zn photocatalyst: photophysical properties and mechanistic understanding

Supplementary files

Article information

Article type
Research Article
Submitted
11 Dec 2020
Accepted
29 Jan 2021
First published
01 Feb 2021

Inorg. Chem. Front., 2021,8, 2078-2087

Visible light photoredox by a (ph,ArNacNac)2Zn photocatalyst: photophysical properties and mechanistic understanding

K. Singh, V. S. and D. Adhikari, Inorg. Chem. Front., 2021, 8, 2078 DOI: 10.1039/D0QI01466D

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