Suitable commercial catalysts for the synthesis of oxymethylene dimethyl ethers

• Published in: Reaction chemistry & engineering Vol. 8; no. 4; pp. 917 - 932
• Main Authors: Mantei, Franz, Kopp, Sebastian, Holfelder, Anna, Flad, Elisa, Kloeters, Daniela, Kraume, Matthias, Salem, Ouda
• Format: Journal Article
• Language: English
• Published: Cambridge Royal Society of Chemistry 28.03.2023
• Subjects: Carrier density; Catalysts; Chemical synthesis; Diesel fuels; Distillation; Ethers; Fuel cells; Internal combustion engines; Ion exchange; Ion exchange resins; Methanol; Nitrogen oxides; Reduction; Thermal stability
• ISSN: 2058-9883; 2058-9883
• DOI: 10.1039/d2re00508e

OME have diesel fuel like properties with almost soot-free combustion, which can enable a reduction of nitrogen oxides. This makes them promising candidates for internal combustion engines as blends or neat fuel. Moreover, OME are addressed as environmentally benign solvents and as hydrogen dense carriers for fuel cells. OME are produced from methanol which can be produced sustainably, allowing a significant overall reduction of CO 2 emissions. Various catalysts have been investigated for OME synthesis focusing on selectivity and activity. This study concentrates on commercial heterogeneous catalysts and compares not only the conversions, selectivities and the target product yield but also the activity, side product formation and thermal stability of the synthesis products. Various ion exchange resins, zeolites and Nafion catalysts were applied for the OME synthesis in a batch autoclave at 60 °C for the aqueous reaction systems methanol/paraformaldehyde and the anhydrous reaction system OME 1 /trioxane. Investigations of the synthesis products in a micro distillation setup showed that all applied catalysts lead to active species in the synthesis product, negatively impacting its thermal stability. This indicates that a synthesis product handling step is necessary prior to the downstream purification. Based on these investigations, ion exchange resins are identified as the most suitable for industrial OME synthesis due to their higher activity and lower side product formation. The commercial catalysts Amberlyst 15 and 46 show high activities and selectivities for the OME synthesis with very low side product formations. However, the synthesis products of all investigated catalysts need to be neutralized before distillation.