Low temperature methane coupling in a Pd-based membrane reactor with UV activation

“…Methane can be considered as a promising feedstock for technical hydrogen obtaining. Nevertheless, its nonoxidative coupling is accompanied by significant energy absorption and occurs under high temperatures with low productivity or requires a forced activation [5]. Steam reforming of methane [6,7], or its high-temperature conversion, flowing due to partial oxidation by oxygen, are much more economically feasible [8].…”

Influence of the support structure and composition of Ni–Cu-based catalysts on hydrogen production by methanol steam reforming

“…Methane can be considered as a promising feedstock for technical hydrogen obtaining. Nevertheless, its nonoxidative coupling is accompanied by significant energy absorption and occurs under high temperatures with low productivity or requires a forced activation [5]. Steam reforming of methane [6,7], or its high-temperature conversion, flowing due to partial oxidation by oxygen, are much more economically feasible [8].…”

Influence of the support structure and composition of Ni–Cu-based catalysts on hydrogen production by methanol steam reforming

“…High performance, low cost and stability of reported SPES-Agcoupled with Fischer-Tropsch synthesis (FTS) reactions. The results demonstrated the superiority of OTCMTR to all previously proposed configurations Basov et al, (2013). identified the nonoxidative coupling of methane to hydrocarbons C-2 and above at 475-555 K by UV activation with hydrogen removed from the reaction zone through a palladium membrane increased CH4 conversion Ghorbani et al, (2013).…”

Chemical Waste and Allied Products

“…In the past, methods for producing hydrogen from natural gas and alcohols obtained from biomass attracted extensive attention [3–5] . It seems to be a favorable pathway to use methane as raw material, but its high temperature reaction conditions make this process complex and expensive [6–8] . Based on the liquid sunshine system, methanol steam reforming (MSR) that can efficiently produce hydrogen with low CO concentration below 300 °C has been widely recognized and successfully applied in energy industry [9–13] .…”

“…[3][4][5] It seems to be a favorable pathway to use methane as raw material, but its high temperature reaction conditions make this process complex and expensive. [6][7][8] Based on the liquid sunshine system, methanol steam reforming (MSR) that can efficiently produce hydrogen with low CO concentration below 300 °C has been widely recognized and successfully applied in energy industry. [9][10][11][12][13] Therefore, the research committed to methanol dehydrogenation catalysts is increasing rapidly.…”

An InO_x Surface Enrichment on the Cu Nanoparticles for the Methanol Steam Reforming