Abstract
Direct oxidation of methane (DOM) into high-value C2+ products using molecular oxygen (O(2)) is essential for the sustainable production of clean energy and bulk chemicals, but is still challenging due to the difficult C-H activation and uncontrollable C-C coupling process. Herein, we design and construct the Fe-(μ-O)-Zn dual-atom sites by supporting Fe and Zn atoms on ZSM-5 (Fe(1)-Zn(1)/ZSM-5), which achieves the DOM by O(2) to acetic acid under ambient temperature and pressure. The Fe-(μ-O)-Zn dual-atom sites yield an acetic acid productivity of 3006 μmol•g(cat)(-1)•h(-1) with 86.8% selectivity (total C2+ products selectivity of 93.0%) for at least 20 hours at 25 (o)C and atmospheric pressure. The mutual electronic modulation between Fe and Zn shifts the d-band center of Fe 3d in Fe-(μ-O)-Zn dual-atom sites upwards, which promotes the formation and stabilization of highly reactive Fe=O species through O(2) photodissociation and thereby enhances the C-H bond activation of CH(4). The Fe-(μ-O)-Zn dual-atom reaction sites (spatial distance of 2.7 Å) boost the C-C coupling of key CH(3) and HCHO intermediate species, which steadily produce acetic acid and other C2+ oxygenates. This work would broaden the avenue towards the sustainable conversion of methane to value-added C2+ products under ambient temperature and pressure.