Catalytic Photochemical Deracemization via Short-Lived Intermediates

Johannes Großkopf; Thorsten Bach

doi:10.1002/anie.202308241

Catalytic Photochemical Deracemization via Short-Lived Intermediates

Johannes Großkopf, Thorsten Bach

Chair of Organic Chemistry 1

Technical University of Munich

Research output: Contribution to journal › Review article › peer-review

32 Scopus citations

Abstract

Upon irradiation in the presence of a suitable chiral catalyst, racemic compound mixtures can be converted into enantiomerically pure compounds with the same constitution. The process is called photochemical deracemization and involves the formation of short-lived intermediates. By opening different reaction channels for the forward reaction to the intermediate and for the re-constitution of the chiral molecule, the entropically disfavored process becomes feasible. Since the discovery of the first photochemical deracemization in 2018, the field has been growing rapidly. This review comprehensively covers the research performed in the area and discusses current developments. It is subdivided according to the mode of action and the respective substrate classes. The focus of this review is on the scope of the individual reactions and on a discussion of the mechanistic details underlying the presented reaction.

Original language	English
Article number	e202308241
Journal	Angewandte Chemie International Edition in English
Volume	62
Issue number	50
DOIs	https://doi.org/10.1002/anie.202308241
State	Published - 11 Dec 2023

Keywords

Asymmetric Catalysis
Enantioselectivity
Homogeneous Catalysis
Photocatalysis
Photochemistry

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10.1002/anie.202308241

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title = "Catalytic Photochemical Deracemization via Short-Lived Intermediates",

abstract = "Upon irradiation in the presence of a suitable chiral catalyst, racemic compound mixtures can be converted into enantiomerically pure compounds with the same constitution. The process is called photochemical deracemization and involves the formation of short-lived intermediates. By opening different reaction channels for the forward reaction to the intermediate and for the re-constitution of the chiral molecule, the entropically disfavored process becomes feasible. Since the discovery of the first photochemical deracemization in 2018, the field has been growing rapidly. This review comprehensively covers the research performed in the area and discusses current developments. It is subdivided according to the mode of action and the respective substrate classes. The focus of this review is on the scope of the individual reactions and on a discussion of the mechanistic details underlying the presented reaction.",

keywords = "Asymmetric Catalysis, Enantioselectivity, Homogeneous Catalysis, Photocatalysis, Photochemistry",

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T1 - Catalytic Photochemical Deracemization via Short-Lived Intermediates

AU - Großkopf, Johannes

AU - Bach, Thorsten

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N2 - Upon irradiation in the presence of a suitable chiral catalyst, racemic compound mixtures can be converted into enantiomerically pure compounds with the same constitution. The process is called photochemical deracemization and involves the formation of short-lived intermediates. By opening different reaction channels for the forward reaction to the intermediate and for the re-constitution of the chiral molecule, the entropically disfavored process becomes feasible. Since the discovery of the first photochemical deracemization in 2018, the field has been growing rapidly. This review comprehensively covers the research performed in the area and discusses current developments. It is subdivided according to the mode of action and the respective substrate classes. The focus of this review is on the scope of the individual reactions and on a discussion of the mechanistic details underlying the presented reaction.

AB - Upon irradiation in the presence of a suitable chiral catalyst, racemic compound mixtures can be converted into enantiomerically pure compounds with the same constitution. The process is called photochemical deracemization and involves the formation of short-lived intermediates. By opening different reaction channels for the forward reaction to the intermediate and for the re-constitution of the chiral molecule, the entropically disfavored process becomes feasible. Since the discovery of the first photochemical deracemization in 2018, the field has been growing rapidly. This review comprehensively covers the research performed in the area and discusses current developments. It is subdivided according to the mode of action and the respective substrate classes. The focus of this review is on the scope of the individual reactions and on a discussion of the mechanistic details underlying the presented reaction.

KW - Asymmetric Catalysis

KW - Enantioselectivity

KW - Homogeneous Catalysis

KW - Photocatalysis

KW - Photochemistry

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DO - 10.1002/anie.202308241

M3 - Review article

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Catalytic Photochemical Deracemization via Short-Lived Intermediates

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