Catalyst-free partial oxidation of methane under ambient conditions boosted by mechanical stirring-enhanced ultrasonic cavitation
Yingtong Pan, Ruofan Li, Ling Zhang, Ji‐Xuan Liu, Wenzhong Wang, Guo‐Jun Zhang
Abstract
The partial oxidation of methane (POM) into value-added C1 chemicals (e.g., CH3OH, HCHO, and CO) offers a promising approach for natural gas utilization under mild conditions. However, existing POM systems often rely on complex catalyst designs and the addition of extra oxidants. Here, we developed a catalyst-free POM system by integrating mechanical stirring with a low-frequency ultrasonic field. A high production rate of C1 chemicals (129.26 µmol h−1) and methane conversion rate (22%) were achieved under ambient conditions (298 K, PCH4 = 0.1 bar, PO2 = 0.1 bar, PN2 = 0.8 bar). Mechanism studies revealed that the introduction of mechanical stirring amplified the ultrasonic cavitation effect, promoting the in-situ release of reactive oxygen species. Reaction pathway investigation confirmed that hydroxyl radicals facilitated the cleavage of methane C-H bonds and that oxygen participated in the generation of POM products. This strategy provides a sustainable avenue for the value-added conversion of methane. The partial oxidation of methane to value-added C₁ chemicals is a promising approach for natural gas utilization. Here the authors report a catalyst-free oxidation method via mechanical stirring and ultrasonic cavitation.