Methane to High-Value Chemicals at Room Temperature as a Cover Story in JACS

Highly dispersed dual Au and Cu species enable efficient and selective photocatalytic conversion of methane to methanol and oxygenates on ZnO using O₂ as the oxidant operated at ambient temperature, resulting in a nearly 100% selectivity and 14.1% apparent quantum yield at 365 nm. Check the cover story here.

Direct and efficient oxidation of methane to methanol and the related liquid oxygenates provides a promising pathway for sustainable chemical industry, while still remaining an ongoing challenge owing to the dilemma between methane activation and overoxidation. Here, ZnO with highly dispersed dual Au and Cu species as cocatalysts enables efficient and selective photocatalytic conversion of methane to methanol and one-carbon (C1) oxygenates using O₂ as the oxidant operated at ambient temperature. The optimized AuCu–ZnO photocatalyst achieves up to 11225 μmol·g^–1·h^–1 of primary products (CH₃OH and CH₃OOH) and HCHO with a nearly 100% selectivity, resulting in a 14.1% apparent quantum yield at 365 nm, much higher than the previous best photocatalysts reported for methane conversion to oxygenates. In situ EPR and XPS disclose that Cu species serve as photoinduced electron mediators to promote O₂ activation to ^•OOH, and simultaneously that Au is an efficient hole acceptor to enhance H₂O oxidation to ^•OH, thus synergistically promoting charge separation and methane transformation. This work highlights the significances of co-modification with suitable dual cocatalysts on simultaneous regulation of activity and selectivity. Check the paper here.