Methane oxidation to ethanol by a molecular junction photocatalyst.

Methane, the main component of natural and shale gas, is a significant carbon source for chemical synthesis. The direct partial oxidation of methane to liquid oxygenates under mild conditions(1-3) is an attractive pathway, but the inertness of the molecule makes it challenging to achieve simultaneously high conversion and high selectivity towards a single target product. This difficulty is amplified when aiming for more valuable products that require C-C coupling(4,5). Whereas selective partial methane oxidation processes(1-3,6-9) have thus typically generated C(1) oxygenates(6,7), recent reports have documented photocatalytic methane conversion to the C(2) oxygenate ethanol with low conversions but good-to-high selectivities(4,5,8-12). Here we show that the intramolecular junction photocatalyst covalent triazine-based framework-1 with alternating benzene and triazine motifs(13,14) drives methane coupling and oxidation to ethanol with a high selectivity and significantly improved conversion. The heterojunction architecture not only enables efficient and long-lived separation of charges after their generation, but also preferential adsorption of H(2)O and O(2) to the triazine and benzene units, respectively. This dual-site feature separates C-C coupling to form ethane intermediates from the sites where •OH radicals are formed, thereby avoiding over-oxidation. When loaded with Pt to further boost performance, the molecular heterojunction photocatalyst generates ethanol in a packed-bed flow reactor with greatly improved conversion that results in an apparent quantum efficiency of 9.4%. We anticipate that further developing the 'intramolecular junction' approach will deliver efficient and selective catalysts for C-C coupling, pertaining, but not limited, to methane conversion to C(2+) chemicals.