Citation: D. J. Segobia, A. F. Trasarti, C. R. Apesteguía. Effect of the catalyst preparation method on the performance of Ni-supported catalysts for the synthesis of saturated amines from nitrile hydrogenation[J]. Chinese Journal of Catalysis, ;2019, 40(11): 1693-1703. doi: 10.1016/S1872-2067(18)63179-1 shu

Effect of the catalyst preparation method on the performance of Ni-supported catalysts for the synthesis of saturated amines from nitrile hydrogenation

Catalysis Science and Engineering Research Group (GICIC), INCAPE, UNL-CONICET, CCT Conicet-Paraje El Pozo, (3000) Santa Fe, Argentina

Received Date: 3 October 2018
Revised Date: 12 October 2018

The liquid-phase hydrogenation of butyronitrile to saturated amines was studied on sili-ca-supported Ni catalysts prepared by either incipient-wetness impregnation (Ni/SiO₂-I) or ammonia (Ni/SiO₂-A) methods. A Ni/SiO₂-Al₂O₃-I sample was also used. Ni/SiO₂-I was a non-acidic catalyst containing large Ni⁰ particles of low interaction with the support, while Ni/SiO₂-A was an acidic catalyst due to the presence of Ni²⁺ species in Ni phyllosilicates of low reducibility. Ni/SiO₂-I formed essentially butylamine (80%), and dibutylamine as the only byproduct. In contrast, Ni/SiO₂-A yielded a mixture of dibutylamine (49%) and tributylamine (45%), being the formation of butylamine almost completely suppressed. The selective formation of secondary and tertiary amines on Ni/SiO₂-A was explained by considering that butylamine is not release to the liquid phase during the reaction because it is strongly adsorbed on surface acid sites contiguous to Ni⁰ atoms, thereby favoring the butylimine/butylamine condensation to higher amines between adsorbed species.
- Nitrile hydrogenation,
- Saturated amines,
- Ni-supported catalysts,
- Ni-phyllosilicates,
- Catalyst preparation
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