Influence of reaction parameters on the activity of ruthenium based catalysts for glycerol steam reforming

• Published in: Applied catalysis. B, Environmental Vol. 121-122; pp. 40 - 49
• Main Authors: Gallo, Alessandro, Pirovano, Claudio, Ferrini, Paola, Marelli, Marcello, Psaro, Rinaldo, Santangelo, Saveria, Faggio, Giuliana, Dal Santo, Vladimiro
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier B.V 13.06.2012; Elsevier
• Subjects: Catalysis; Chemistry; Coke; Exact sciences and technology; General and physical chemistry; Glycerol; Hydrogen; Magnesium aluminum mixed oxide; Ruthenium; Steam reforming; Theory of reactions, general kinetics. Catalysis. Nomenclature, chemical documentation, computer chemistry; Glycerol; Magnesium aluminum mixed oxide; Steam reforming; Ruthenium; Hydrogen; Coke; Water; Methane; Aluminium oxide; Oxidation reduction; Catalytic reaction; Stability; Magnesium oxide; Transition metal; Selectivity; High temperature; Conversion; Supported catalyst; Coke deposition; Heterogeneous catalysis; Impregnation; Platinoid; Catalyst; Environmental protection
• ISSN: 0926-3373; 1873-3883
• DOI: 10.1016/j.apcatb.2012.03.013

[Display omitted] ► Low loaded ruthenium based catalyst supported on magnesium aluminum mixed oxide. ► Heterogeneous catalysts for glycerol steam reforming to hydrogen rich mixtures. ► High temperature and low glycerol concentrations result in highest performances. ► High glycerol concentrations result in low, but stable, activity. ► Coke and by-products are formed at low temperatures and high glycerol concentrations. Mg(Al)O supported Ru catalysts with low loading of active metal (0.6wt.%), obtained from simple inorganic salts, were tested, for the first time, in the steam reforming (SR) of glycerol to hydrogen rich mixtures. The catalysts, obtained by simple wet impregnation of Ru salts on a Mg(Al)O mixed oxide followed by high temperature oxidation/reduction treatments, were systematically characterized by numerous complementary techniques, both before and after their use in SR reaction. The changes of the performances (activity, selectivity and stability) of Ru/Mg(Al)O catalysts were studied, produced by varying reaction temperature (450–650°C) at fixed glycerol concentration (10wt.% in water), and by varying glycerol concentration (10–40wt.% in water) at fixed reaction temperature (550°C). The best performances (in terms of glycerol conversion, H2 yield and CO2 selectivity), at lowest reaction temperature, were obtained operating at 10wt.% glycerol and 550°C. Correspondingly, catalysts showed glycerol conversion, H2 yield and CO2 selectivity close to 100%. Methane was practically absent, CO selectivity was lower than 3.5% and coke deposition quite scarce (1.1mgCgcat−1h−1). However, at this temperature, catalysts exhibited stable, although lower, performances up to 40wt.% glycerol concentrations. Significantly, catalytic performances could be improved increasing reaction temperature up to 650°C keeping other advantages.