The catalytic oxidization of CS2 over atmospheric particles and some oxide catalysts was explored through FT-IR, MS and a fixed-bed stainless steel reactor. The results show that atmospheric particles and some oxide catalysts exhibited considerable oxidizing activities for CS2 at ambient temperature. The reaction products are mainly COS and elemental sulfur, even CO2 on some catalysts. Among the catalysts, CaO has the strongest catalytic activity for oxidizing CS2. Fe2O3 is weaker than CaO. The catalytic activity for AI2O3 reduces considerably compared with the former two catalysts, and SiO2 the weakest. Atmospheric particle samples’ catalytic activity is between Fe2O3’s and AI2O3’s. The atmospheric particle sample collected mainly consists of Ca(AI2Si2O8) · 4H2O, which is also the main component of cement. COS, the main product, is formed by the catalytic oxidization of CS2 with adsorbed “molecular” oxygen over the catalysts’ surfaces. The concentration of adsorbed oxygen over catalysts’ surfaces may be th The catalytic oxidization of CS2 over atmospheric particles and some oxide catalysts was explored through FT-IR, MS and a fixed-bed stainless steel reactor. The results show that atmospheric particles and some oxide supplies Among the catalysts, CaO has the strongest catalytic activity for oxidizing CS2. Fe2O3 is weaker than CaO. The catalytic activity for AI2O3 reduces agents compared with the former two catalysts, and SiO2 the weakest. Atmospheric particle samples’ catalytic activity is between Fe2O3’s and AI2O3’s. The atmospheric particle sample collected consists mainly of Ca (AI2Si2O8) .4H2O, which is also the main component of cement. catalytic oxidization of CS2 with adsorbed “molecular ” oxygen over the catalysts’ surfaces. The concentration of adsorbed oxygen over cata lysts’ surfaces may be th