Facile synthesis based on novel carbon-supported cyanogel of structurally ordered Pd3Fe/C as electrocatalyst for formic acid oxidation

Liu, ZY (Liu, Zhenyuan)[ 1 ] ; Fu, GT (Fu, Gengtao)[ 1,2 ]*; Li, JH (Li, Jiahui)[ 1 ] ; Liu, ZQ (Liu, Zhenqi)[ 1 ] ; Xu, L (Xu, Lin)[ 1 ] ; Sun, DM (Sun, Dongmei)[ 1 ] ; Tang, YW (Tang, Yawen)[ 1 ]*（唐亚文）

[ 1 ] Nanjing Normal Univ, Sch Chem & Mat Sci, Jiangsu Collaborat Innovat Ctr Biomed Funct Mat, Jiangsu Key Lab New Power Batteries, Nanjing 210023, Jiangsu, Peoples R China

[ 2 ] Nanyang Technol Univ, Sch Chem & Biomed Engn, Singapore 637459, Singapore

NANO RESEARCH，201809,11(9),4686-4696

A novel carbon-supported cyanogel (C@cyanogel)-derived strategy is used to synthesize an intermetallic Pd3Fe/C compound of the desired ordered Pd3Fe phase with a small particle size. The novelty of this work lies in using carbon-supported (K2PdCl4)-Cl-II/K4FeII(CN)(6) cyanogel as a reaction precursor, generated through the substitution of two chloride ligands by the nitrogen ends of the cyanide ligands on the metal center. The inherent nature of cyanogels can effectively suppress the movement of Pd-0 and Fe-0 nuclei in the crystal, benefiting the formation of the intermetallic, which is otherwise challenging via traditional synthesis techniques. The ordered Pd3Fe/C catalyst exhibits excellent catalytic activity and good cycle stability for the formic acid oxidation (FAO) reaction relative to the properties of disordered Pd3Fe/C and commercial Pd/C catalysts, demonstrating that the ordered Pd3Fe/C is a promising replacement for commercial Pd-based catalysts. The outstanding performance can be ascribed to the full isolation of active sites in the ordered Pd3Fe structure and the modified electronic structure of the active components. This work provides an effective and novel route to obtain Pd-based intermetallic compounds with potential applications in a wide range of electrocatalysis.

文章链接：

https://link.springer.com/article/10.1007%2Fs12274-018-2051-7