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- Title
Mechanism of the Decomposition of Hydrazine Monohydrate on Pd/Al<sub>2</sub>O<sub>3</sub> Studied by in Situ IR Spectroscopy.
- Authors
Matyshak, V. A.; Silchenkova, O. N.; Ilichev, A. N.; Bykhovsky, M. Ya.; Mnatsakanyan, R. A.
- Abstract
Pd-containing catalysts (1% Pd/Al2O3 and 5% Pd/Al2O3) supported on aluminum oxide were studied in the decomposition reaction of hydrazine monohydrate. According to in situ IR-spectroscopic data, hydrazine monohydrate was adsorbed in a linear form on the coordinatively unsaturated sites of the catalyst surface. As the temperature was increased, the adsorbed hydrazine monohydrate lost a water molecule with a change in the geometry of the molecular complex. The adsorption of hydrazine on a support and its diffusion onto palladium clusters is a more advantageous process than direct adsorption on active sites. This circumstance shows that the hydrazine adsorbed on the support can be an intermediate in the process of its decomposition. The test catalysts had a maximum activity at a temperature of about 100°C. At temperatures in a range of 100−120°C, the ratio between hydrogen and nitrogen concentrations in the reaction products was 2, which corresponds to 100% selectivity for hydrogen. The selectivity decreased significantly with the reaction temperature. The high selectivity for hydrogen at low temperatures was explained by the fact that N2H4 was chemisorbed through the formation of hydrogen–metal bonds. The hydrogen–metal bond strength in such a complex is higher than the nitrogen–metal bond strength; hence, the N−H bond breaking barrier is lower than the N−N bond breaking barrier, and this fact led to the breaking of an N–H bond and the preservation of an N–N bond. At elevated temperatures, some of the formed hydrogen atoms recombined, and the other reacted with the surface complexes of hydrazine to form the intermediate NH3−NH3, in which N–N bond breaking led to the appearance of ammonia molecules in the gas phase.
- Subjects
HYDRAZINE; HYDRAZINES; AMMONIA gas; HIGH temperatures; MOLECULAR shapes; HYDROGEN atom; STEAM reforming
- Publication
Kinetics & Catalysis, 2023, Vol 64, Issue 6, p826
- ISSN
0023-1584
- Publication type
Article
- DOI
10.1134/S0023158423060101