Syngas production from natural gas via catalytic partial oxidation using ceramic monolith catalyst at short contact time and elevated pressure

“…Therefore, it made the activation and reduction of CO 2 become possible. This typical process was expressed in Scheme 1 and simply summarized by following reactions according to previous literature [20,27,28,48,49]:…”

Mesoporous nanocrystalline ceria–zirconia solid solutions supported nickel based catalysts for CO2 reforming of CH4

“…Therefore, it made the activation and reduction of CO 2 become possible. This typical process was expressed in Scheme 1 and simply summarized by following reactions according to previous literature [20,27,28,48,49]:…”

Mesoporous nanocrystalline ceria–zirconia solid solutions supported nickel based catalysts for CO2 reforming of CH4

“…[1][2][3] For over a century, much attention from both academia and industries has been paid to syngas production towards more efficient, sustainable, and environmentally benign conversion of fossil fuel feedstocks. [4][5][6][7][8] Due to the large reserves of natural gas worldwide along with the recent boom of shale gas/biogas, methane becomes an ideal "precursor" of syngas not just for today but also for the foreseeable future. [9][10][11] There are typically three routes for methane-syngas conversion to date, namely, partial oxidation of methane (POM), steam reforming of methane (SRM) and dry reforming of methane (DRM).…”

Toward highly efficient in situ dry reforming of H₂S contaminated methane in solid oxide fuel cells via incorporating a coke/sulfur resistant bimetallic catalyst layer

“…Few data are available in the literature dealing with high pressure CPO tests, [8,[22][23][24] but this is a critical element for experimentation and safety analysis, due to the more severe conditions related to the flammability properties of the gaseous reactant mixtures.…”

Catalytic Partial Oxidation Coupled with Membrane Purification to Improve Resource and Energy Efficiency in Syngas Production