Bimetallic PdFe catalysts in hydrodechlorination of diclofenac: Influence of support nature, metal deposition sequence and reduction condition

Monometallic palladium and bimetallic palladium-iron catalysts (1 wt% Pd, 10 wt% Fe) were prepared by sequential (denoted as -s) and co-(denoted as -c) impregnation of alumina and silica - zirconia (ZS) supports with metal nitrates. After reduction with H2 at 320 and 30 & DEG;C the catalysts were tested in hydrodechlorination of diclofenac in water at 30 & DEG;C in batch and flow-type reactors. The alumina-supported catalysts were more active than the ZS-supported ones, while the bimetallic catalysts were more efficient than the monometallic Pd ones. The co-impregnated bimetallic catalysts showed higher efficiencies than the catalysts prepared by the sequential deposition of metals. Pd/Al2O3 and PdFe/Al2O3-c provided the same rate of DCF conversion in the batch reactor after both types of preliminary reduction, opening the way for energy saving. The catalysts were studied by XRD, TEM, SEM-EDX, low-temperature N2 physisorption, Mo & BULL;ssbauer spectroscopy, DRIFT-CO and by XPS after in situ reduction at 320 & DEG;C and ex-situ reduction at 30 & DEG;C. The improvements in catalyst efficiency resulted from wider pores, formation of PdFe alloys or Pd-Fe-Ox species on the surface, high Pd0/Pd2} ratio, low extent of Pd encapsulation with the support and especially its coordinately unsaturated sites. The encapsulation degree was the lowest in the co-impregnated catalysts.

Automated summary

Monometallic palladium and bimetallic palladium-iron catalysts were prepared using sequential and co-impregnation methods. The bimetallic catalysts showed higher efficiency in hydrodechlorination reaction compared to the monometallic Pd catalysts. The co-impregnation method resulted in better catalyst performance. The improved efficiency was attributed to wider pores, formation of PdFe alloys or Pd-Fe-Ox species on the surface, high Pd0/Pd2 ratio, low extent of Pd encapsulation, and coordinately unsaturated sites.