Effect of palladium precursors on liquid phase hydrogenation over silica-supported palladium catalysts

Abstract

Liquid phase hydrogenation of 1-hexene under mild conditions has been investigated on a series of silica (SiO[subscript 2] and MCM-41) supported Pd catalysts prepared from different Pd precursors such as Pd(NO3)[subscript 2], PdCl[subscript 2], and Pd(OAc)[subscript 2]. For both SiO[subscript 2] and MCM-41 supports, use of PdCl[subscript 2] as a Pd precursor resulted in the smallest Pd particle size, the highest Pd dispersion, and consequently the highest hydrogenation activities. Deactivation of the silica supported Pd catalysts in liquid phase hydrogenation was found to be dependent on the palladium particle size. Smaller Pd particles prepared from PdCl[subscript 2] showed greater metal sintering after 1.5-h batch reaction, whereas leaching of Pd was found to a significant degree for the ones prepared from Pd(NO[subscript 3])[subscript 2] and Pd(OAc)[subscript 2] (larger Pd particles). An optimum Pd particle size may be needed in order to minimize such loss and enhance Pd dispersion. MCM-41 was partially collapsed during reaction resulting in lower CO chemisorption of the spent Pd/MCM-41 catalyst than that of Pd/SiO[subscript 2]. The optimum reduction temperature for the PdCl[subscript 2]/SiO[subscript 2] was determined to be ca. 150 degree celsius. The results suggest that a complete decomposition of PdH[subscript 2] to Pd[superscript 0] probably increased the amount of active surface Pd available for the reaction