Mechanistic insights into coke suppression and enhanced olefin selectivity in mixed metal oxide-modified SAPO-34 for high-performance methanol-to-olefins catalysis

Mechanistic insights into coke suppression and enhanced olefin selectivity in mixed metal oxide-modified SAPO-34 for high-performance methanol-to-olefins catalysis

Blog Article

The methanol-to-olefins (MTO) process is a key catalytic route for light olefin production, yet challenges related to catalyst deactivation and coke formation persist.In this study, we investigate the catalytic performance of SAPO-34 (SP) and a modified SAPO-34 catalyst incorporating a mixed metal oxide of indium oxide and cerium probios intelliflora for dogs oxide (SPM) to enhance selectivity, stability, and coke resistance.A combination of experimental and theoretical approaches, including catalyst characterization, MTO catalytic testing, and molecular dynamics (MD) simulations, was employed to elucidate the impact of mixed metal oxide incorporation on catalyst properties.

The results indicate that SPM exhibits significantly higher total olefin selectivity (85.7 %) compared to SP (76.6 %), with improved stability and a catalytic lifetime approximately twice as long.

Furthermore, SPM demonstrates a higher propylene-to-ethylene (P/E) ratio, reaching 2.9 at the initial stage compared to 1.5 for SP.

The incorporation of mixed metal oxides enhances mesoporosity and modifies acid site distribution, reducing excessive secondary reactions and mitigating coke formation.MD simulations confirm that SPM inhibits the formation of formaldehyde species, a key coke precursor, while promoting coke oxidation, thereby extending catalyst lifespan.These stedy stand aid findings suggest that mixed metal oxide incorporation is an effective strategy for optimizing SAPO-34-based catalysts for sustainable MTO applications.