Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

This Special Issue on “Catalysts for Syngas Production”, included in the Catalysts open access journal, shows new research about the development of catalysts and catalytic routes for syngas production, and the optimization of the reaction conditions for the process. This issue includes ten articles about the different innovative processes for syngas production. Synthesis gas (or syngas) is a mixture of hydrogen and carbon monoxide, with different chemical composition and H2/CO molar ratios, depending on the feedstock and production technology used. Syngas may be obtained from alternative sources to oil, such as natural gas, coal, biomass, organic wastes, etc. Syngas is a very good intermediate for the production of high value compounds at the industrial scale, such as hydrogen, methanol, liquid fuels, and a wide range of chemicals. Accordingly, efforts should be made on the co-feeding of CO2 with syngas, as an alternative for reducing greenhouse gas emissions. In addition, more syngas will be required in the near future, in order to satisfy the demand for synfuels and high value chemicals.

Research & information: general --- Environmental economics --- x%Co-Ni/Ce-Al2O3 --- steam reforming --- regeneration --- thermal stability --- anti-coking ability --- carbon --- combined Co-Fe species --- deactivation --- hydrogen production --- methane decomposition --- Ni catalysts --- combustion method --- dry reforming of methane --- RWGS reaction --- improved stability --- CH4 --- CeO2 --- dry reforming --- MgO --- Ni --- TiO2 --- syngas production --- hydrogen sulfide --- carbon dioxide --- Ni-Mo sulfide semiconductor --- non-thermal plasma --- methane steam reforming --- bench scale --- effectiveness factor --- Sulfur tolerant water gas shift catalyst --- steam/gas ratio --- Mo-Co/alkali/Al2O3 catalyst --- catalyst deactivation --- syngas --- H2 production --- Hydrogen --- Low Temperature Steam Reforming --- Rh4(CO)12 cluster --- microemulsion synthesis --- CeZr oxide --- Zr oxide --- heterogeneous catalysis --- solar thermochemical --- iridium catalyst --- rhodium catalyst --- catalytic cracking --- ethylene --- carbon nanofilaments --- hydrogen --- x%Co-Ni/Ce-Al2O3 --- steam reforming --- regeneration --- thermal stability --- anti-coking ability --- carbon --- combined Co-Fe species --- deactivation --- hydrogen production --- methane decomposition --- Ni catalysts --- combustion method --- dry reforming of methane --- RWGS reaction --- improved stability --- CH4 --- CeO2 --- dry reforming --- MgO --- Ni --- TiO2 --- syngas production --- hydrogen sulfide --- carbon dioxide --- Ni-Mo sulfide semiconductor --- non-thermal plasma --- methane steam reforming --- bench scale --- effectiveness factor --- Sulfur tolerant water gas shift catalyst --- steam/gas ratio --- Mo-Co/alkali/Al2O3 catalyst --- catalyst deactivation --- syngas --- H2 production --- Hydrogen --- Low Temperature Steam Reforming --- Rh4(CO)12 cluster --- microemulsion synthesis --- CeZr oxide --- Zr oxide --- heterogeneous catalysis --- solar thermochemical --- iridium catalyst --- rhodium catalyst --- catalytic cracking --- ethylene --- carbon nanofilaments --- hydrogen

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

This Special Issue on “Catalysts for Syngas Production”, included in the Catalysts open access journal, shows new research about the development of catalysts and catalytic routes for syngas production, and the optimization of the reaction conditions for the process. This issue includes ten articles about the different innovative processes for syngas production. Synthesis gas (or syngas) is a mixture of hydrogen and carbon monoxide, with different chemical composition and H2/CO molar ratios, depending on the feedstock and production technology used. Syngas may be obtained from alternative sources to oil, such as natural gas, coal, biomass, organic wastes, etc. Syngas is a very good intermediate for the production of high value compounds at the industrial scale, such as hydrogen, methanol, liquid fuels, and a wide range of chemicals. Accordingly, efforts should be made on the co-feeding of CO2 with syngas, as an alternative for reducing greenhouse gas emissions. In addition, more syngas will be required in the near future, in order to satisfy the demand for synfuels and high value chemicals.

x%Co-Ni/Ce-Al2O3 --- steam reforming --- regeneration --- thermal stability --- anti-coking ability --- carbon --- combined Co–Fe species --- deactivation --- hydrogen production --- methane decomposition --- Ni catalysts --- combustion method --- dry reforming of methane --- RWGS reaction --- improved stability --- CH4 --- CeO2 --- dry reforming --- MgO --- Ni --- TiO2 --- syngas production --- hydrogen sulfide --- carbon dioxide --- Ni-Mo sulfide semiconductor --- non-thermal plasma --- methane steam reforming --- bench scale --- effectiveness factor --- Sulfur tolerant water gas shift catalyst --- steam/gas ratio --- Mo–Co/alkali/Al2O3 catalyst --- catalyst deactivation --- syngas --- H2 production --- Hydrogen --- Low Temperature Steam Reforming --- Rh4(CO)12 cluster --- microemulsion synthesis --- CeZr oxide --- Zr oxide --- heterogeneous catalysis --- solar thermochemical --- iridium catalyst --- rhodium catalyst --- catalytic cracking --- ethylene --- carbon nanofilaments --- hydrogen --- n/a --- combined Co-Fe species --- Mo-Co/alkali/Al2O3 catalyst