Direct conversion of methane to formaldehyde and CO on B2O3 catalysts

Direct oxidation of methane to value-added C-1 chemicals (e.g. HCHO and CO) provides a promising way to utilize natural gas sources under relatively mild conditions. Such conversions remain, however, a key selectivity challenge, resulting from the facile formation of undesired fully-oxidized CO2. Here we show that B2O3-based catalysts are selective in the direct conversion of methane to HCHO and CO (similar to 94% selectivity with a HCHO/CO ratio of similar to 1 at 6% conversion) and highly stable (over 100hour time-on-stream operation) conducted in a fixed-bed reactor (550 degrees C, 100 kPa, space velocity 4650mL g(cat)(-1) h(-1)). Combined catalyst characterization, kinetic studies, and isotopic labeling experiments unveil that molecular O-2 bonded to tri-coordinated BO3 centers on B2O3 surfaces acts as a judicious oxidant for methane activation with mitigated CO2 formation, even at high O-2/CH4 ratios of the feed. These findings shed light on the great potential of designing innovative catalytic processes for the direct conversion of alkanes to fuels/chemicals.