Abstract
Ni/ZrO2 catalysts, active and selective for the catalytic partial oxidation of methane to syngas (CH4-CPO), were prepared by the dry impregnation of zirconium oxyhydroxide (Zhy) or monoclinic ZrO2 (Zm), calcination at 1173 K and activation by different procedures: oxidation-reduction (ox-red) or direct reduction (red). The characterization included XRD, FESEM, in situ FTIR and Raman spectroscopies, TPR, and specific surface area measurements. Catalytic activity experiments were carried out in a flow apparatus with a mixture of CH4:O2 = 2:1 in a short contact time. Compared to Zm, Zhy favoured the formation of smaller NiO particles, implying a higher number of Ni sites strongly interacting with the support. In all the activated Ni/ZrO2 catalysts, the Ni–ZrO2 interaction was strong enough to limit Ni aggregation during the catalytic runs. The catalytic activity depended on the activation procedures; the ox-red treatment yielded very active and stable catalysts, whereas the red treatment yielded catalysts with oscillating activity, ascribed to the formation of Niδ+ carbide-like species. The results suggested that Ni dispersion was not the main factor affecting the activity, and that active sites for CH4-CPO could be Ni species at the boundary of the metal particles in a specific configuration and nuclearity.
Highlights
The global energy demand is expected to rise by 30% between today and 2040
zirconium oxyhydroxide (Zhy), heated at 1173 K transformed into monoclinic ZrO2, Zm, as shown by X-ray diffraction (XRD) (JCPDF card 37-1484) (Figure 1a)
Ni metal particles supported on monoclinic ZrO2, prepared via the impregnation of two different starting materials, were active for the partial oxidation of CH4
Summary
The global energy demand is expected to rise by 30% between today and 2040. In this scenario, the use of natural gas as an energy source is expected to increase by 45%in the 20 years, according to the World Energy Outlook 2017—International EnergyAgency [1]. The global energy demand is expected to rise by 30% between today and 2040. In this scenario, the use of natural gas as an energy source is expected to increase by 45%. The conversion of natural gas, mainly constituted by methane, into highly valuable products has become challenging [1,2,3,4]. The catalytic partial oxidation of methane (CH4 -CPO) is a valid alternative because it is mildly exothermic and can produce syngas in a ratio (H2 /CO = 2) suitable for methanol or Fischer–Tropsch synthesis [5,6,7,10,11,12,13]
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