State Key Laboratory of Organic Geochemistry, Guangdong Key Laboratory of Environment and Resources, Guangzhou Institute of Geochemistry, Chinese Academy of Sciences, Guangzhou 510640, China.
J Hazard Mater. 2011 Aug 15;192(1):1-7. doi: 10.1016/j.jhazmat.2011.03.109. Epub 2011 Apr 7.
In this study the concentrations and distribution of sixteen polycyclic aromatic hydrocarbons (PAHs) were investigated in gas and total suspended particle (TSP) samples collected during daytime and night time. The sampling locations included an electronic waste dismantling workshop (EW), a plastic recycling workshop (PW) and a waste incineration field (WF) in Guiyu, China. A large residential area (RA) in this region was used as a control site. In the daytime, the highest concentration was found at WF (1041 ng m(-3)); while in the night time the highest concentration was found outside of EW (744 ng m(-3)). Comparison between work hours (daytime) and rest hours (night time) displayed that the total PAHs (gas+particulate phase) concentrations and the percentages of PAHs associated with TSP were higher at night than those in the daytime in all sampling workshops except WF. Source diagnostic-ratio analysis revealed that unwanted materials and smoldering honeycomb coals were the main sources of PAHs in EW, WF and PW. Benzo[a]pyrene equivalent [BaPeq] concentrations calculated by using the toxic equivalent factors [TEFs] suggested that the occupational exposure levels were not significantly high when compared with other occupational exposure. Additionally, our study suggested that the smoldering of unwanted materials could produce much more toxic PAHs compounds.
本研究调查了 16 种多环芳烃(PAHs)在白天和夜间采集的气体和总悬浮颗粒物(TSP)样品中的浓度和分布。采样地点包括中国贵屿的一个电子废物拆解车间(EW)、一个塑料回收车间(PW)和一个废物焚烧场(WF)。该地区的一个大型住宅区(RA)被用作对照点。在白天,WF 的浓度最高(1041ngm(-3));而在夜间,EW 外的浓度最高(744ngm(-3))。工作时间(白天)和休息时间(夜间)的比较显示,除 WF 外,所有采样车间的总多环芳烃(气体+颗粒物相)浓度和与 TSP 相关的多环芳烃百分比均高于夜间高于白天。源解析-比值分析表明,EW、WF 和 PW 中的 PAHs 主要来源于不可燃材料和闷烧蜂窝煤。使用毒性等效因子 [TEFs] 计算的苯并[a]芘等效浓度 [BaPeq] 表明,与其他职业暴露相比,职业暴露水平并不显著高。此外,我们的研究表明,不可燃材料的闷烧可能会产生更多毒性更高的多环芳烃化合物。
