We report on the use of In as an effective H2 production promoter in a Cu/SiO2 catalyst for the steam reforming of methanol. To date, In promotion has been limited to noble metals because of its tendency to "bury" other metals thus compromising the catalytic activity. Here, we prepared a silica-supported Cu-In catalyst via a urea assisted co-precipitation method that showed a higher H2 productivity compared to the monometallic catalyst and a remarkable H2/CO2 molar ratio of almost 3 at 220 oC. Through XPS, XRPD and HRTEM-EDX along with H2- and CO-TPR, H2O-TPD, and N2O titrations, supported by computational modeling, we attributed such superior performances to an easier H2O activation due to improved electronic properties of the Cu phase, that is, its loweroxidation state via electron density transfer from the InOx buffer phase as a 1D "necklace" structures crucially mediating the interaction of small Cu nanoparticles (2.6 nm) and silica.
Discovering indium as hydrogen production booster for a Cu/SiO2 catalyst in steam reforming of methanol
Filippo Bossola;Thantip Roongcharoen;Claudio Evangelisti;Luca Sementa;Alessandro Fortunelli;Vladimiro Dal Santo
2021
Abstract
We report on the use of In as an effective H2 production promoter in a Cu/SiO2 catalyst for the steam reforming of methanol. To date, In promotion has been limited to noble metals because of its tendency to "bury" other metals thus compromising the catalytic activity. Here, we prepared a silica-supported Cu-In catalyst via a urea assisted co-precipitation method that showed a higher H2 productivity compared to the monometallic catalyst and a remarkable H2/CO2 molar ratio of almost 3 at 220 oC. Through XPS, XRPD and HRTEM-EDX along with H2- and CO-TPR, H2O-TPD, and N2O titrations, supported by computational modeling, we attributed such superior performances to an easier H2O activation due to improved electronic properties of the Cu phase, that is, its loweroxidation state via electron density transfer from the InOx buffer phase as a 1D "necklace" structures crucially mediating the interaction of small Cu nanoparticles (2.6 nm) and silica.| File | Dimensione | Formato | |
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Applied Catalysis B Environmental 297 (2021) 120398.pdf
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Applied Catalysis B Environmental 297 (2021) 120398_SI.pdf
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