Gas-phase isopropanol degradation by nonthermal plasma combined with Mn-Cu/-Al2O3

In this study, the dielectric barrier discharge (DBD) induced by nonthermal plasma (NTP) technology was used for isopropanol (IPA) degradation. IPA, intermediate, final product, and ozone concentrations were analyzed using GC-MS, carbon dioxide detector, and ozone detector. The experimental flow rate and concentration were fixed to 1 L/min and 1200 ppm +/- 10%, respectively. Different reaction procedures were proposed for self-made metal catalyst combined with a plasma system (plasma alone and gamma-Al2O3 combined with plasma, Cu (5 wt%)/gamma-Al2O3 combined with plasma, Mn (3 wt%)-Cu (5 wt%)/gamma-Al2O3 combined with plasma). In addition, the effect of the carrier gas oxygen content (0%, 20%, and 100%) on IPA conversion and intermediate and carbon dioxide selectivity was also investigated. The results revealed that the Mn (F)-Cu/gamma-Al2O3 combined with plasma exhibited more efficient IPA conversion. In the 100% oxygen environment, the IPA conversion rate increased from 79.32 to 99.99%, and carbon dioxide selectivity increased from 3.82 to 50.23%. IPA was completely converted after 60 min of plasma treatment with the acetone selectivity, carbon dioxide selectivity, and tail ozone concentration of 26.71% +/- 1.27%, 50.23% +/- 0.56%, and 1761 +/- 11 ppm, respectively. This study proved that the current single planar DBD configuration is an effective advanced treatment technology for the decomposition of VOCs.

Automated summary

In this study, dielectric barrier discharge induced by nonthermal plasma technology was used for isopropanol degradation, with the best results found when combining Mn (F)-Cu/gamma-Al2O3 with plasma, achieving complete conversion of IPA in a 100% oxygen environment. The study confirmed the effectiveness of the current single planar DBD configuration as an advanced treatment technology for the decomposition of VOCs.