Simulation of the transition metal-based cumulative oxidative potential in East Asia and its emission sources in Japan

The aerosol oxidative potential (OP) is considered to better represent the acute health hazards of aerosols than the mass concentration of fine particulate matter (PM2.5). The proposed major contributors to OP are water soluble transition metals and organic compounds, but the relative magnitudes of these compounds to the total OP are not yet fully understood. In this study, as the first step toward the numerical prediction of OP, the cumulative OP (OPtm*) based on the top five key transition metals, namely, Cu, Mn, Fe, V, and Ni, was defined. The solubilities of metals were assumed constant over time and space based on measurements. Then, the feasibility of its prediction was verified by comparing OPtm* values based on simulated metals to that based on observed metals in East Asia. PM2.5 typically consists of primary and secondary species, while OPtm* only represents primary species. This disparity caused differences in the domestic contributions of PM2.5 and OPtm*, especially in large cities in western Japan. The annual mean domestic contributions of PM2.5 were 40%, while those of OPtm* ranged from 50 to 55%. Sector contributions to the OPtm* emissions in Japan were also assessed. The main important sectors were the road brake and iron-steel industry sectors, followed by power plants, road exhaust, and railways.

Automated summary

This study investigates the oxidative potential (OP) of aerosols and its health impacts compared to fine particulate matter (PM2.5). By defining cumulative OPtm*, it was possible to predict OP based on key transition metals, showing discrepancies in domestic contributions of PM2.5 and OPtm* in large cities in western Japan. OPtm* was found to have a higher contribution than PM2.5 in these areas, indicating potential differences in health hazards.