The effect of Y-zeolite acidity on m-xylene transformation reactions

Abstract: m-Xylene transformation has been studied on as-prepared H-Y and a series of dealuminated Y zeolite catalysts. The conversion of m-xylene was found to increase initially with acidity, however, decreases subsequently. It has been proposed that the high concentration of acid sites in the H-Y catalyst increases paring reaction, in addition to the well-known isomerization and disproportionation pathways. A significant decrease was observed with respect to disproportionation/paring (D/Pa) ratio versus reaction tempe… Show more

“…3 shows the changes in the conversion of m-xylene and the selectivity to o-and p-xylene as a function of the reaction temperature for a reaction time of 1 h on the catalysts neutralized with different alkali metal oxides. Here, propane, benzene, toluene and trimethylbenzene were also found as byproducts, as reported by Inui et al [7]; however, their selectivities were disregarded as there were no target compounds in this study. The neutralized catalysts exhibited higher m-xylene conversions than the un-neutralized, as shown in A).…”

“…Therefore, an alternative route is required for the syntheses of high value o-and p-xylenes from m-xylene [1][2][3][4][5][6]. Studies on the syntheses of o-and p-xylenes using Y-type zeolites, which have the homologous structure of FAU (fauzasite), have been reported by several research groups [7,8], partly due to their increased chemical and thermal stability. Zeolite-Y is made ultra stable by the removal of aluminum from its framework.…”

“…Zeolite-Y is made ultra stable by the removal of aluminum from its framework. However, FAU has large cavities inside its crystal channel structure, which can lead to the risk of rapid coke formation [7] when the intrinsic strength and concentration of the acid sites inside the cavity are too great. Coke formation particularly occurred at the external surface of the crystals, as there is little to restrict the growth of fused-ring aromatics, i.e., the precursors of aromatic coke.…”

Control of acidity on the external surface of zeolite Y for m-xylene isomerization using a mechanochemical neutralization method

“…3 shows the changes in the conversion of m-xylene and the selectivity to o-and p-xylene as a function of the reaction temperature for a reaction time of 1 h on the catalysts neutralized with different alkali metal oxides. Here, propane, benzene, toluene and trimethylbenzene were also found as byproducts, as reported by Inui et al [7]; however, their selectivities were disregarded as there were no target compounds in this study. The neutralized catalysts exhibited higher m-xylene conversions than the un-neutralized, as shown in A).…”

“…Therefore, an alternative route is required for the syntheses of high value o-and p-xylenes from m-xylene [1][2][3][4][5][6]. Studies on the syntheses of o-and p-xylenes using Y-type zeolites, which have the homologous structure of FAU (fauzasite), have been reported by several research groups [7,8], partly due to their increased chemical and thermal stability. Zeolite-Y is made ultra stable by the removal of aluminum from its framework.…”

“…Zeolite-Y is made ultra stable by the removal of aluminum from its framework. However, FAU has large cavities inside its crystal channel structure, which can lead to the risk of rapid coke formation [7] when the intrinsic strength and concentration of the acid sites inside the cavity are too great. Coke formation particularly occurred at the external surface of the crystals, as there is little to restrict the growth of fused-ring aromatics, i.e., the precursors of aromatic coke.…”

Control of acidity on the external surface of zeolite Y for m-xylene isomerization using a mechanochemical neutralization method

“…The major sources of xylene are catalytic naphtha reforming and pyrolysis of gasoline [1]. However, xylene isomers from these sources generally do not match demand proportions as chemical intermediates, and further comprise of ethyl benzene, which is difficult to separate or convert [2].…”

Kinetics of toluene methylation over USY-zeolite catalyst in a riser simulator

“…27 The bimolecular pathway, associated with disproportionation on adjacent acid sites, is favored in zeolites as the Si/Al ratio decreases (greater Brønsted acid site density) and the pore size of the zeolite increases. [24][25][26]28 Considerations of reaction temperature and the greater acid site density in zeolites indicate that the bimolecular mechanism, which produces toluene and trimethylbenzene, should occur when producing p-xylene from DMF using H-Y and H-BEA zeolite. 29 The role of strong acid sites within H-Y and H-BEA for catalyzing the dehydration of Diels−Alder cycloadducts of furans, while not promoting isomerization, is of primary interest.…”

Inhibition of Xylene Isomerization in the Production of Renewable Aromatic Chemicals from Biomass-Derived Furans