What question did this study set out to answer?

This research aims to develop an efficient method for forming P(O)-N bonds using paired electrolysis in organic synthesis.

June 1, 2026

Paired Electrolysis-Driven P(O)–N Bond Formation via Reductive Cross-Coupling of Nitroarenes with Phosphine Oxides

Key Points

This research aims to develop an efficient method for forming P(O)-N bonds using paired electrolysis in organic synthesis.
Utilized paired electrolysis-promoted reductive cross-coupling reactions without metal catalysts or chemical reductants.
Synthesis involved nitroarenes and phosphine oxides to create phosphinamides, phosphonamides, and phosphoramides.
Investigated mechanistic pathways including radical and Atherton-Todd pathways.
P(O)-N bonds formed efficiently with broad functional group compatibility.
Chemo-selective P(O)-N bond formation characterized by radical involvement and various product types.

Abstract

The efficient construction of the P(O)-N bond is crucial in organic synthesis. P(O)-N bond formations with nitroarenes and phosphine oxides were accomplished via paired electrolysis-promoted reductive cross-coupling reactions under metal-catalyst- and chemical-reductant-free conditions. The combination of paired electrolysis with reductive coupling enabled P(O)-N bond formation in a chemo-selective fashion and exhibited broad functional group tolerance, which allows for the synthesis of phosphinamides, phosphonamides, and phosphoramides and provides access to late-stage functionalization. Mechanistic studies indicated that both radical and Atherton-Todd pathways are operative in the electro-reductive coupling.

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Paired Electrolysis-Driven P(O)–N Bond Formation via Reductive Cross-Coupling of Nitroarenes with Phosphine Oxides

Key Points

Abstract

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