Photoelectrocatalytic arene C–H amination

Photoelectrochemical cells are widely studied for solar energy conversion. However, they have rarely been used for the synthesis of high added-value organic molecules. Here we describe a strategy to use haematite, an abundant and robust photoanode, for non-directed arene C–H amination. Under illumination, the photogenerated holes in haematite oxidize electron-rich arenes to radical cations, which further react with azoles to give nitrogen heterocycles of medicinal interest. Unusual ortho selectivity was achieved, probably due to a hydrogen-bonding interaction between the substrates and the hexafluoroisopropanol co-solvent. The method exhibits broad scope and is successfully applied for the late-stage functionalization of several pharmaceutical molecules.

Photoelectrocatalytic arene C–H amination

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High-throughput parallel testing of ten photoelectrochemical cells for water splitting: case study on the effects of temperature in hematite photoanodes

Durable Perovskite Solar Cells with 24.5% Average Efficiency: The Role of Rigid Conjugated Core in Molecular Semiconductors

Shortwave Infrared-Sensitive, Narrowband Organic Upconversion Devices with a Gain

High-throughput parallel testing of ten photoelectrochemical cells for water splitting: case study on the effects of temperature in hematite photoanodes