Characterization of PM2.5-borne heavy metal pollution from industrial sources and human health risk assessment

To investigate the pollution characteristics of PM_2.5 and its associated heavy metals, we collected and analyzed PM_2.5 samples from five industrial sources in Handan, namely production chimneys, workshops, factory areas, and two control points. Macroscopic and microscopic perspectives were employed to determine the contents of 11 heavy metals (Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Ba, and Pb) and one metalloid (As). The results revealed that the total average mass concentrations of the 12 metal elements followed the order: chimney (9598.64 ng·m⁻³) > workshop (7332.94 ng·m⁻³) > factory area (3104.31 ng·m⁻³) > control point B (2073.21 ng·m⁻³) > control point A (1004.74 ng·m⁻³). Fe, Ti, Zn, and Ni were the primary contributors to total metal content at each sampling site. Seasonal variations in heavy metal concentrations were minimal. Fe had the highest mass concentration among the metals at all sites (>60 %), whereas the Cr (VI) and As concentrations significantly exceeded the permitted levels. The particle types with a relatively high number in single particles emitted from chimney were mineral particles (31.58 %), iron-containing metal oxides (26.32 %), and soot aggregates (23.68 %). Mixed particles are primarily present as external mixtures. The AERMOD model simulation indicated significant regional dispersion of PM_2.5 within 10 km, which was corroborated by sample analysis at the nearby control point. Indoor/outdoor (I/O) ratio modeling demonstrated that heavy metal concentrations were generally higher in workshops than in factory areas, suggesting the potential diffusion of some heavy metals from workshops to the factory atmosphere. Enrichment factor (EF) analysis showed that Fe was highly enriched (EF > 3000) at all sampling sites, with EFs at the control points exceeding 1000. These findings suggest that industrial emissions from the foundry industry in Handan contributed significantly to the ambient atmospheric Fe levels. Health risk assessment indicated a substantial non-carcinogenic risk (CR; hazard index >1) and a moderate CR (10⁻⁴ ≤ CR < 10⁻³) for the study area. Co, Cr (VI), Mn, and Pb pose significant non-CR, whereas Cr (VI) and As have been identified as key contributors to CR.