1. Catalytic transfer hydrogenation of biomass-derived furfural to furfuryl alcohol over in-situ prepared nano Cu-Pd/C catalyst using formic acid as hydrogen source.
- Author
-
Du, Juan, Zhang, Jiaren, Sun, Yong, Jia, Wenlong, Si, Zhihao, Gao, He, Tang, Xing, Zeng, Xianhai, Lei, Tingzhou, Liu, Shijie, and Lin, Lu
- Subjects
- *
CATALYSIS , *HYDROGENATION , *BIOMASS , *HYDROGEN , *COPRECIPITATION (Chemistry) - Abstract
Graphical abstract Highlights • Over physically mixed CuO-Pd/C furfural hydrogenation was performed with formic acid. • CuO firstly dissolved into Cu2+ by formic acid, then Cu2+ was reduced by the Pd-H. • Pd promoted the furfural conversion and Cu improved the furfuryl alcohol selectivity. • Cu-Pd alloys functioned well in this reaction with 98.1% furfuryl alcohol yield. • In-situ prepared Cu-Pd/C exhibited an excellent recycle stability. Abstract Catalytic transfer hydrogenation (CTH) of bio-derived furfural (FF) to furfuryl alcohol (FFA) was performed using the physically mixed CuO-Pd/C as catalyst and formic acid (FA) as hydrogen donor. The evolution investigation of Cu showed the precursor CuO firstly dissolved into Cu2+ by FA and then formed coordination polymer-copper(II), which uniformly dispersed in reaction solution of 1, 4-dioxane. Subsequently the Cu2+ was in-situ reduced and Cu-Pd alloys formed simultaneously. The in-situ prepared nano Cu-Pd/C catalyst exhibited the best performance with a complete FF conversion and FFA selectivity of 98.1%. Reaction conditions test suggested that the FFA selectivity was greatly dependent on the Cu content. The underlying mechanism revealed that the Pd in Cu-Pd alloys mainly promoted the FF conversion by enhancing hydrogen adsorption, while the nano Cu for increasing FFA selectivity; the Cu-Pd alloys functioned in synergistic way. Leaching and recycling tests demonstrated an excellent stability of the Cu-Pd/C catalyst. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF