In this study, we reported on the effect of promoting Ni/ZrO2 catalysts with Ce, Ca (two different loadings), and Y for the aqueous-phase reforming (APR) of methanol. We mainly focused on the effect of the redox properties of ceria and the basicity provided by calcium or yttrium on the activity and selectivity of Ni in this reaction. A systematic characterization of the catalysts was performed using complementary methods such as XRD, XPS, TPR, CO2-TPD, H2 chemisorption, HAADF-STEM, and EDS-STEM. Our results reveal that the improvement in reducibility derived from the incorporation of Ce did not have a positive impact on catalytic behaviour thus contrasting with the results reported in the literature for other Ce-based catalytic compositions. On the contrary, the available Ni-metallic surface and the presence of weak basic sites derived from Ca incorporation seem to play a major role on the catalytic performance for APR of methanol. The best performance was found for a Ce-free catalyst with a molar Ca content of 4%.
A series of NiO–CeO2 mixed oxide catalysts have been synthesized by a modified coprecipitation method at three different pH values (pH = 8, 9, and 10). The NiO–CeO2 mixed oxide samples were characterized by TGA, XRD, inductively coupled plasma atomic emission spectroscopy (ICP-AES), FTIR, Brunauer–Emmett–Teller (BET) surface area, H2 temperature-programmed reduction (H2-TPR), and electron microscopy (high-angle annular dark-field transmission electron microscopy/energy-dispersive X-ray spectroscopy (HAADF-TEM/EDS)). The catalytic activities of the samples for soot oxidation were investigated under loose and tight contact conditions. The catalysts exhibited a high BET surface area with average crystal sizes that varied with the pH values. Electron microscopy results showed the formation of small crystallites (~5 nm) of CeO2 supported on large plate-shaped particles of NiO (~20 nm thick). XRD showed that a proportion of the Ni2+ was incorporated into the ceria network, and it appeared that the amount on Ni2+ that replaced Ce4+ was higher when the synthesis of the mixed oxides was carried out at a lower pH. Among the synthesized catalysts, Ni-Ce-8 (pH = 8) exhibited the best catalytic performance.
A family of iron-doped
manganese-related hollandites, K
x
Mn
1–
y
Fe
y
O
2−δ
(0 ≤
y
≤ 0.15),
with high performance in CO oxidation
have been prepared. Among them, the most active catalyst, K
0.11
Mn
0.876
Fe
0.123
O
1.80
(OH)
0.09
, is able to oxidize more than 50% of CO at room temperature. Detailed
compositional and structural characterization studies, using a wide
battery of thermogravimetric, spectroscopic, and diffractometric techniques,
both at macroscopic and microscopic levels, have provided essential
information about this never-reported behavior, which relates to the
oxidation state of manganese. Neutron diffraction studies evidence
that the above compound stabilizes hydroxyl groups at the midpoints
of the tunnel edges as in isostructural β-FeOOH. The presence
of oxygen and hydroxyl species at the anion sublattice and Mn
3+
, confirmed by electron energy loss spectroscopy, appears
to play a key role in the catalytic activity of this doped hollandite
oxide. The analysis of these detailed structural features has allowed
us to point out the key role of both OH groups and Mn
3+
content in these materials, which are able to effectively transform
CO without involving any critical, noble metal in the catalyst formulation.
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