Factors influencing hydrogenation and decomposition of H2O2 over Pd-Au catalysts supported on activated carbon cloth (ACC)

A1 Originalartikel i en vetenskaplig tidskrift (referentgranskad)


Interna författare/redaktörer


Publikationens författare: Davood Gudarzi, Ilkka Turunen, Markku Heinonen, Tapio Salmi
Publiceringsår: 2015
Tidskrift: Topics in Catalysis
Volym: 58
Nummer: 14
Artikelns första sida, sidnummer: 1019
Artikelns sista sida, sidnummer: 1035
eISSN: 1572-9028


Abstrakt

The bimetallic Pd–Au catalysts were prepared by simultaneous co-impregnation or consequent impregnation of supports by palladium and gold precursors. The catalytic reactions were performed batch-wise in a Parr stainless steel autoclave and methanol (220 ml) was used as solvent. A series of experiments were conducted to study effects of several variables and conditions on the final H2O2 destruction activity of the catalysts. The factors studied where : the surface chemistry of the support, the amount and ratio of palladium and gold, the catalyst preparation method, the heat treatment of the catalysts in H2 and air, the reaction medium, and reaction temperature. As a conclusion, H2O2 destruction activities of the catalysts were strongly affected by the surface chemistry of the support and the amount and ratio of palladium and gold. Bimetallic catalysts prepared by co-impregnation of Pd and Au were less destructive than the corresponding ones prepared by consequent impregnation. The catalysts supported on activated carbon cloth (ACC) oxidized by nitric acid were considerably less destructive than the corresponding ones on non-oxidized ACC. H2O2 destruction activity of the catalysts on oxidized ACC were highly affected by the heat treatment in H2 and air at different temperatures. Using water instead of methanol as reaction medium substantially speeded up H2O2 destruction. Furthermore, increasing the reaction temperature accelerated destruction of H2O2. Catalytic destruction of H2O2 via its decomposition was considerably low as compared to hydrogenation.

Senast uppdaterad 2020-26-02 vid 04:40