"Transition Metal as Dopant on Nickel Boride .Their Catalytic Activity Effect on Hydrogenation Reactions "

DELICIA ACOSTA; NORMA RAMIREZ; ELEONORA ERDAMNN; ELIO GONZO; HUGO DESTEFANIS

CATALYSIS TODAY

Elsevier B.V.

Año: 2008 vol. 133 p. 49 - 55

0920-5861

Nickel borides doped with elements of first transition series (Cr, Mn, Fe, Co, Cu, and Zn) MNiB, 4% (w/w) respect to Ni, and prepared with the same method as NiB, were used in the glucose and the nitrobenzene hydrogenation reactions. The amorphous catalysts were prepared by chemical reduction of nickel and metallic (Cr, Mn, Fe, Co, Cu, and Zn) salts with borane–tetrahydrofurane (BH3–THF) complex in aprotic solvent (THF anhydrous). Different techniques were used to characterize these materials. The MNiB amorphous structure was verified by XRD. The results show that bimetallic borides follow a pattern related to the nature of the dopants metal. The oxidation stability, magnetic susceptibility and catalytic effect are correlated with parameters of each dopants metal. SEM studies show the same spongy-morphology in all cases. The logarithm of the ratio between bimetallic boride and nickel borides specific rates, for nitrobenzene hydrogenation, follow a linear relation with respect to the same relation for glucose hydrogenation. These results demonstrate that the dopants effect on the free activation energy is the same for both reaction systems. This effect could be related with electronic modifications introduced by the dopants metal on nickel boride.3–THF) complex in aprotic solvent (THF anhydrous). Different techniques were used to characterize these materials. The MNiB amorphous structure was verified by XRD. The results show that bimetallic borides follow a pattern related to the nature of the dopants metal. The oxidation stability, magnetic susceptibility and catalytic effect are correlated with parameters of each dopants metal. SEM studies show the same spongy-morphology in all cases. The logarithm of the ratio between bimetallic boride and nickel borides specific rates, for nitrobenzene hydrogenation, follow a linear relation with respect to the same relation for glucose hydrogenation. These results demonstrate that the dopants effect on the free activation energy is the same for both reaction systems. This effect could be related with electronic modifications introduced by the dopants metal on nickel boride. Keywords: Nickel borides; Catalyst; Glucose; Nitrobenzene hydrogenationNickel borides; Catalyst; Glucose; Nitrobenzene hydrogenation