FePd nanowires modified with cyclodextrin as improved catalysts: effect of the alloy composition on colloidal stability and catalytic capacity

In the present work, FePd nanowires of different compositions, namely Fe85Pd15, Fe65Pd35, Fe55Pd45 and Fe0Pd100, were synthesized by electrodeposition into the nanopores of alumina membranes. The samples were characterized by XRD, SEM, EDS, XPS, and magnetometry. The surface of the nanowires was functionalized with a cyclodextrin derivative (beta CDMOD14) to obtain stable aqueous dispersions. A comprehensive study on the relationship between the alloy composition and the catalytic capacity of FePd nanowires (FePdNWs) modified with beta CDMOD14 was conducted through the analysis of the rate constants (k(obs)) of the reduction reaction of 4-nitrophenol to 4-aminophenol with sodium borohydride mediated by the FePdNWs in water. The highest value of k(obs) was observed for Fe55Pd45 NWs, but the catalytic performance of Fe65Pd35 NWs was similar to the previous one, in spite of its lower Pd content. The presence of Fe atoms and the synthesis method promotes the formation of an fcc phase in the alloy, which shows higher catalytic activity than pure Pd, possibly because of a synergistic effect exerted by Fe. The catalysts can be easily recovered by taking advantage of their magnetic properties, to be reused after reactivation with beta CDMOD14.

Automated summary

In this study, the catalytic performance of FePd nanowires with different compositions was investigated through functionalization and analysis of reaction rate constants. The results showed that Fe55Pd45 nanowires exhibited the highest catalytic activity, while Fe65Pd35 nanowires showed similar performance despite their lower Pd content. The presence of Fe atoms and the formation of an fcc phase in the alloy may contribute to the synergistic effect on catalytic activity.