Plasma-Catalytic Removal of NOx in Mobile and Stationary Sources

“…Nevertheless, at operating temperatures ≥225 °C, the NO x removal efficiency in the presence of plasma was lower than that for the catalyst alone, which is attributed to the decreased C1/NO x ratio (number of moles of carbon in the hydrocarbon reducing agent per number of moles of nitrogen in NO x ) owing to the partial oxidation of n -heptane to CO 2 in the plasma stage as discussed above. This result is in good agreement with that in previous reports that the performance of the hydrocarbon SCR process largely depends on the C1/NO x ratio. , The reaction mechanism of the hydrocarbon SCR for NO x has been reported in the literature. ,, …”

“…50,51 The reaction mechanism of the hydrocarbon SCR for NO x has been reported in the literature. 9,11,53 To explain the partial oxidation of n-heptane in the honeycomb discharge at ambient temperature, the optical emission spectra of the honeycomb discharge at the surrounding power electrode were recorded. The plasma discharge was performed at 100 ppm NO, 86 ppm n-heptane, 2.4% water vapor, and a SEI of 25 J/L.…”

“…Hydrocarbon selective catalytic reduction (HC-SCR) has been successfully used for NO x removal within a narrow temperature window (250–350 °C). − The use of non-thermal plasma in conjunction with a catalyst has been proposed to expand the temperature window with the view of lowering the temperature. − This comes from a plasma state consisting of energetic electrons, excited species, radicals, and ions. Indeed, energetic electrons produced by dielectric barrier discharge (DBD) plasma have energies in the range of 1–10 eV .…”

“…DBD plasma is commonly used in research to investigate the removal of NO x . ,,− However, from the viewpoint of practical application with high throughput, the main disadvantage of the DBD plasma is the size of the discharge gap (a few millimeters), which is a significant limitation of this technique. The narrow discharge gap and the use of dielectric barrier have been shown to be responsible for the pressure drop and low mechanical resistance in a variety of reactors .…”

High-Throughput NO_x Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

“…Nevertheless, at operating temperatures ≥225 °C, the NO x removal efficiency in the presence of plasma was lower than that for the catalyst alone, which is attributed to the decreased C1/NO x ratio (number of moles of carbon in the hydrocarbon reducing agent per number of moles of nitrogen in NO x ) owing to the partial oxidation of n -heptane to CO 2 in the plasma stage as discussed above. This result is in good agreement with that in previous reports that the performance of the hydrocarbon SCR process largely depends on the C1/NO x ratio. , The reaction mechanism of the hydrocarbon SCR for NO x has been reported in the literature. ,, …”

“…50,51 The reaction mechanism of the hydrocarbon SCR for NO x has been reported in the literature. 9,11,53 To explain the partial oxidation of n-heptane in the honeycomb discharge at ambient temperature, the optical emission spectra of the honeycomb discharge at the surrounding power electrode were recorded. The plasma discharge was performed at 100 ppm NO, 86 ppm n-heptane, 2.4% water vapor, and a SEI of 25 J/L.…”

“…Hydrocarbon selective catalytic reduction (HC-SCR) has been successfully used for NO x removal within a narrow temperature window (250–350 °C). − The use of non-thermal plasma in conjunction with a catalyst has been proposed to expand the temperature window with the view of lowering the temperature. − This comes from a plasma state consisting of energetic electrons, excited species, radicals, and ions. Indeed, energetic electrons produced by dielectric barrier discharge (DBD) plasma have energies in the range of 1–10 eV .…”

“…DBD plasma is commonly used in research to investigate the removal of NO x . ,,− However, from the viewpoint of practical application with high throughput, the main disadvantage of the DBD plasma is the size of the discharge gap (a few millimeters), which is a significant limitation of this technique. The narrow discharge gap and the use of dielectric barrier have been shown to be responsible for the pressure drop and low mechanical resistance in a variety of reactors .…”

High-Throughput NO_x Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

“…4 However, the use of diesel fuel gives rise to the emission of NO x , which is a concern because it is harmful to human health as well as to the environment. 5 Furthermore, the standard requirements for diesel emission are becoming increasingly stringent in the emission regulations and are represented by a significant decrease in the amount of chemical pollution resulting from diesel exhaust gases. 6 Consequently, the manufacturers of diesel engines are under pressure to lower the emissions of pollutants caused by diesel to comply with standard requirements.…”

Enhancing the Selective Catalytic Reduction of NO_x at Low Temperature by Pretreatment of Hydrocarbons in a Gliding Arc Plasma

Effective generation of atmospheric pressure plasma in a sandwich-type honeycomb monolith reactor by humidity control