Carbonaceous Aerosol Characteristics in Outdoor and Indoor Environments of Nanchang, China, during Summer 2009

Abstract

ABSTRACT A study of carbonaceous aerosol was initiated in Nanchang, a city in eastern China, for the first time. Daily and diurnal (daytime and nighttime) PM2.5 (particulate matter with aerodynamic diameter ≤2.5 μm) samples were collected at an outdoor site and in three different indoor environments (common office, special printing and copying office, and student dormitory) in a campus of Nanchang University during summer 2009 (5–20 June). Daily PM10 (particulate matter with aerodynamic diameter ≤10 μm) samples were collected only at the outdoor site, whereas PM2.5 samples were collected at both indoor and outdoor sites. Loaded PM2.5 and PM10 samples were analyzed for organic and elemental carbon (OC, EC) by thermal/optical reflectance following the Interagency Monitoring of Protected Visual Environments—Advanced (IMPROVE-A) protocol. Ambient mass concentrations of PM10 and PM2.5 in Nanchang were compared with the air quality standards in China and the United States, and revealed high air pollution levels in Nanchang. PM2.5 accounted for about 70% of PM10, but the ratio of OC and EC in PM2.5 to that in PM10 was higher than 80%, which indicated that OC and EC were mainly distributed in the fine particles. The variations of carbonaceous aerosol between daytime and nighttime indicated that OC was released and formed more rapidly in daytime than in nighttime. OC/EC ratios were used to quantify secondary organic carbon (SOC). The differences in SOC and SOC/OC between daytime and nighttime were useful in interpreting the secondary formation mechanism. The results of (1) OC and EC contributions to PM2.5 at indoor sites and the outdoor site; (2) indoor–outdoor correlation of OC and EC; (3) OC–EC correlation; and (4) relative contributions of indoor and outdoor sources to indoor carbonaceous aerosol indicated that OC indoor sources existed in indoor sites, with the highest OC emissions in I2 (the special printing and copying office), and that indoor EC originated from outdoor sources. The distributions of eight carbon fractions in emissions from the printer and copier showed obviously high OC1 (>20%) and OC2 (∼30%), and obviously low EC1−OP (a pyrolyzed carbon fraction) (<10%), when compared with other sources. IMPLICATIONS Ambient PM2.5 and PM10 in Nanchang showed serious pollution levels. OC and EC were mainly distributed in the fine particle fraction. Interestingly, daytime and nighttime carbonaceous aerosol and SOC and SOC/OC values were compared and indicated that OC was released and formed more rapidly in daytime. From analysis of the distribution of OC and EC, indoor–outdoor correlation, OC–EC correlation, and the relative contributions of indoor and outdoor sources to indoor carbonaceous aerosol, we confirmed the presence of indoor OC sources and limited indoor EC sources. Carbon fractions in emissions from the printer and copier showed obviously high OC1 and OC2 contributions and low EC1−OP percentages. The study contributes a significant reference for the control of indoor carbonaceous sources.