A review of recent advances in catalytic combustion of VOCs on perovskite-type catalysts

“…By use of doping, nonnoble metal oxides have become more preferred than noble metal catalysts due to their relatively high activity and far lower cost for the oxidation of methane and/or VOCs by improving the design and synthesis of porous structures. [13][14][15] Among the nonnoble metal catalysts, the perovskite-type catalyst (ABO 3 ) is one of the best catalytic materials due to its special structure and properties for catalytic combustion of CH 4 and VOCs. Doroftei et al 16 indicated that simple nanocrystalline SrMnO 3 perovskite can be considered as a promising catalyst in low-temperature (T<500°C) combustion reactions of aliphatic hydrocarbons.…”

“…7 Additionally, Gür 7 reviewed CH 4 conversion in solid oxide fuel cells (SOFC) and stated environmental benefits of electrochemical conversion of natural gas (mainly CH 4 ) to electricity as high conversion efficiencies, lower CO 2 emissions per unit of power generated, importantly lower NO x production, environmentally friendly conversion with no noise, no moving parts, and small footprint. [13][14][15] Among the nonnoble metal catalysts, the perovskite-type catalyst (ABO 3 ) is one of the best catalytic materials due to its special structure and properties for catalytic combustion of CH 4 and VOCs. 8-10 Catalytic combustion can be used to overcome almost all the difficulties mentioned above.…”

Perovskite catalysts for methane combustion: applications, design, effects for reactivity and partial oxidation

“…By use of doping, nonnoble metal oxides have become more preferred than noble metal catalysts due to their relatively high activity and far lower cost for the oxidation of methane and/or VOCs by improving the design and synthesis of porous structures. [13][14][15] Among the nonnoble metal catalysts, the perovskite-type catalyst (ABO 3 ) is one of the best catalytic materials due to its special structure and properties for catalytic combustion of CH 4 and VOCs. Doroftei et al 16 indicated that simple nanocrystalline SrMnO 3 perovskite can be considered as a promising catalyst in low-temperature (T<500°C) combustion reactions of aliphatic hydrocarbons.…”

“…7 Additionally, Gür 7 reviewed CH 4 conversion in solid oxide fuel cells (SOFC) and stated environmental benefits of electrochemical conversion of natural gas (mainly CH 4 ) to electricity as high conversion efficiencies, lower CO 2 emissions per unit of power generated, importantly lower NO x production, environmentally friendly conversion with no noise, no moving parts, and small footprint. [13][14][15] Among the nonnoble metal catalysts, the perovskite-type catalyst (ABO 3 ) is one of the best catalytic materials due to its special structure and properties for catalytic combustion of CH 4 and VOCs. 8-10 Catalytic combustion can be used to overcome almost all the difficulties mentioned above.…”

Perovskite catalysts for methane combustion: applications, design, effects for reactivity and partial oxidation

“…This work will describe their defect chemistry which plays an important role in energy applications where the transport properties are the main players. Their defect chemistry is responsible for properties like ionic conductivity [21], mixed conductivity [22], proton conductivity [23], and catalytic conductivity [24] which make perovskite being used for solid oxide fuel cells (SOFC), electrolyte, SOFC electrode, and catalyst.…”

Perovskite-Based Materials for Energy Applications

“…Volatile organic compounds (VOCs), including air and water pollutants, are widely considered as some of the most important components of man-made pollution in modern industrial society. [1][2][3][4][5][6][7] Even though the utilization and emission of VOCs have caused great risks to the environment and human health, VOCs are still extensively employed, especially in the petroleum, chemical, medical and other industrial elds, as irreplaceable raw materials and inevitable by-products. 8 Aromatic compounds, including benzene, toluene, chlorobenzene and so on, are a series of the most commonly encountered VOCs, which are seriously toxic and carcinogenic.…”

Effective removal of aromatic pollutants via adsorption and photocatalysis of porous organic frameworks