What question did this study set out to answer?

This study aims to explore a photochemical approach to enhance copper-catalyzed benzylic C-H phosphatation using minimal substrate.

May 16, 2026

Photochemical Redox Buffering in Copper-Catalyzed Benzylic C–H Phosphatation

Key Points

This study aims to explore a photochemical approach to enhance copper-catalyzed benzylic C-H phosphatation using minimal substrate.
Utilized a Cu/bipyridine catalyst to facilitate reactions under blue-light irradiation.
Conducted mechanistic analysis to assess charge transfer processes between phosphate and copper.
Successfully achieved benzylic C-H phosphatation with limited C-H substrates, showing improved efficiency.
The blue-light irradiation allowed for effective Cu(II) to Cu(I) reduction, enhancing catalytic activity.

Abstract

Copper-catalyzed radical-relay reactions provide a powerful tool for selective C-H functionalization, yet their implementation with peroxide-based oxidants is typically constrained by the requirement for excess C-H substrate. Herein, we present a photochemical approach to circumvent this limitation with a Cu/bipyridine catalyst, enabling benzylic C-H phosphatation with a limiting amount of the C-H substrate. Mechanistic analysis reveals that blue-light irradiation facilitates phosphate-to-copper charge transfer. This process reduces resting-state Cu(II) to Cu(I), which subsequently activates the peroxide to form an alkoxyl radical for hydrogen-atom transfer. This "photochemical redox buffering" effect establishes a unique method to maintain catalytic Cu activity in radical-relay manifolds.

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Photochemical Redox Buffering in Copper-Catalyzed Benzylic C–H Phosphatation

Key Points

Abstract

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