21 PAHs, 27 oxy-PAHs and 32 nitro-PAHs were measured every third day over a year in both gaseous (G) and particulate PM10 (P) phases in ambient air of Grenoble (France). Mean total concentrations (G+P) of PAHs and oxy-PAHs were in the same range and about 10ngm(-3). Nitro-PAHs were 50 to 100 times less concentrated averaging 100pgm(-3). Polycyclic aromatic compound (PAC) concentrations were 5 to 7 times higher in "cold" period (October to March) than in "warm" period (April to September). Seasonal variations may be explained by higher primary emissions from residential heating, especially biomass burning in "cold" season. Meteorological conditions and influence of the geomorphology around Grenoble, with the formation of thermal inversion layers leading to the stagnation of pollutants, were additional key parameters. Maximum individual PAC concentrations were observed during two PM10 pollution events in December and February-March. Chemical processes and secondary formation of oxy- and nitro-PAH were probably enhanced by the accumulation of the pollutants during these events. PAC gas/particle partitioning depended on compound molecular weight and vapour pressure. Gas/particle partitioning of oxy- and nitro-PAHs were evaluated using a multi-phase poly-parameter linear free energy relationship model. The PAC cancer risk was assessed using toxic equivalency factors available in the literature (19 PAHs, 10 nitro-PAHs and 1 oxy-PAH). Overall, particle-bound PACs contributed about 76% of the cancer risk. While PAHs accounted for most of the total PAC cancer risk, oxy- and nitro-PAHs could account for up to 24%. The risk quantification across substance classes is limited by toxicological data availability.
Among the nitrated
and oxygenated polycyclic aromatic hydrocarbons
(NPAHs and OPAHs) are some of the most hazardous substances to public
health, mainly because of their carcinogenicity and oxidative potential.
Despite these concerns, the concentrations and fate of NPAHs and OPAHs
in the atmospheric environment are largely unknown. Ambient air concentrations
of 18 NPAHs, 5 quinones, and 5 other OPAHs were determined at two
urban and one regional background sites in central Europe. At one
of the urban sites, the total (gas and particulate) concentrations
of Σ10OPAHs were 10.0 ± 9.2 ng/m3 in winter and 3.5 ± 1.6 ng/m3 in summer. The gradient
to the regional background site exceeded 1 order of magnitude. Σ18NPAH concentrations were typically 1 order of magnitude lower
than OPAHs. Among OPAHs, 9-fluorenone and (9,10)-anthraquinone were
the most abundant species, accompanied by benzanthrone in winter.
(9,10)-Anthraquinone represented two-thirds of quinones. We found
that a large fraction of the target substance particulate mass was
carried by submicrometer particles. The derived inhalation bioaccessibility
in the PM10 size fraction is found to be ≈5% of
the total ambient concentration of OPAHs and up to ≈2% for
NPAHs. For 9-fluorenone and (9,10)-anthraquinone, up to 86 and 18%,
respectively, were found at the rural site. Our results indicate that
water solubility could function as a limiting factor for bioaccessibility
of inhaled particulate NPAHs and OPAHs, without considerable effect
of surfactant lipids and proteins in the lung lining fluid.
ABSTRACT:A model for gas-particle partitioning of polycyclic aromatic hydrocarbons (PAHs) was evaluated using polyparameter linear free energy relationships (ppLFERs) following a multiphase aerosol scenario. The model differentiates between various organic (i.e., liquid water-soluble (WS)/organic soluble (OS) organic matter (OM), and solid/semisolid organic polymers) and inorganic phases of the particulate matter (PM). Dimethyl sulfoxide and polyurethane were assigned as surrogates to simulate absorption into the abovementioned organic phases, respectively, whereas soot, ammonium sulfate, and ammonium chloride simulated adsorption processes onto PM. The model was tested for gas and PM samples collected from urban and nonurban sites in Europe and the Mediterranean, and the output was compared with those calculated using single-parameter linear free energy relationship (spLFER) models, namely JungePankow, Finizio, and Dachs-Eisenreich. The ppLFER model on average predicted 96 ± 3% of the observed partitioning constants for semivolatile PAHs, fluoranthene, and pyrene, within 1 order of magnitude accuracy with root-mean-square errors (RMSE) of 0.35−0.59 across the sites. This was a substantial improvement compared to Finizio and Dachs-Eisenreich models (37 ± 17 and 46 ± 18% and RMSE of 1.03−1.40 and 0.94−1.36, respectively). The JungePankow model performed better among spLFERs but at the same time showed an overall tendency for overestimating the partitioning constants. The ppLFER model demonstrated the best overall performance without indicating a substantial intersite variability. The ppLFER analysis with the parametrization applied in this study suggests that the absorption into WSOSOM could dominate the overall partitioning process, while adsorption onto salts could be neglected.
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Abstract. Concentrations of polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls (PCBs), and chlorinated pesticides (CPs) were measured in air and precipitation at a background site in central Europe. ∑ PAH concentrations in air and rainwater ranged from 0.7 to 327.9 ng m−3 and below limit of quantification (< LOQ) to 2.1 × 103 ng L−1. The concentrations of PCBs and CPs in rainwater were < LOQ. ∑ PCB and ∑ CP concentrations in air ranged from < LOQ to 44.6 and < LOQ to 351.7 pg m−3, respectively. The potential relationships between PAH wet scavenging and particulate matter and rainwater properties were investigated. The concentrations of ionic species in particulate matter and rainwater were significantly correlated, highlighting the importance of particle scavenging process. Overall, higher scavenging efficiencies were found for relatively less volatile PAHs, underlining the effect of analyte gas-particle partitioning on scavenging process. The particulate matter removal by rain, and consequently PAH wet scavenging, was more effective when the concentrations of ionic species were high. In addition, the elemental and organic carbon contents of the particulate matter were found to influence the PAH scavenging.
Abstract. Nitro-polycyclic aromatic hydrocarbons (NPAH) are ubiquitous in polluted air but little is known about their abundance in background air. NPAHs were studied at one marine and one continental background site, i.e. a coastal site in the southern Aegean Sea (summer 2012) and a site in the central Great Hungarian Plain (summer 2013), together with the parent compounds, PAHs. A Lagrangian particle dispersion model was used to track air mass history. Based on Lagrangian particle statistics, the urban influence on samples was quantified for the first time as a fractional dose to which the collected volume of air had been exposed. At the remote marine site, the 3–4-ring NPAH (sum of 11 targeted species) concentration was 23.7 pg m−3 while the concentration of 4-ring PAHs (6 species) was 426 pg m−3. The most abundant NPAHs were 2-nitrofluoranthene (2NFLT) and 3-nitrophenanthrene. Urban fractional doses in the range of < 0.002–5.4 % were calculated. At the continental site, the Σ11 3–4-ring NPAH and Σ6 4-ring PAH were 58 and 663 pg m−3, respectively, with 9-nitroanthracene and 2NFLT being the most concentrated amongst the targeted NPAHs. The NPAH levels observed in the marine background air are the lowest ever reported and remarkably lower, by more than 1 order of magnitude, than 1 decade before. Day–night variation of NPAHs at the continental site reflected shorter lifetime during the day, possibly because of photolysis of some NPAHs. The yields of formation of 2NFLT and 2-nitropyrene (2NPYR) in marine air seem to be close to the yields for OH-initiated photochemistry observed in laboratory experiments under high NOx conditions. Good agreement is found for the prediction of NPAH gas–particle partitioning using a multi-phase poly-parameter linear free-energy relationship. Sorption to soot is found to be less significant for gas–particle partitioning of NPAHs than for PAHs. The NPAH levels determined in the south-eastern outflow of Europe confirm intercontinental transport potential.
Highlights
Oxidative potential (OP) of PM
2.5
from Canadian cities was studied using a new acellular chemical assay.
Redox potential of simulated lung fluid was highly associated with all physiological OP indicators.
Traffic emissions had the highest OP, followed by industrial emissions and crustal matter.
OP was strongly associated with black carbon and transition metals, especially Cu, Fe, Mn, and Ti.
Organic ligand complexation and aerosol pH were associated with metal solubility and OP.
Abstract. Nitro-monoaromatic hydrocarbons (NMAHs), such as nitrocatechols,
nitrophenols and nitrosalicylic acids, are important constituents of
atmospheric particulate matter (PM) water-soluble organic carbon (WSOC) and
humic-like substances (HULIS). Nitrated and oxygenated derivatives of
polycyclic aromatic hydrocarbons (NPAHs and OPAHs) are toxic and ubiquitous in
the ambient air; due to their light absorption properties, together with
NMAHs, they are part of aerosol brown carbon (BrC). We investigated the
winter concentrations of these substance classes in size-resolved PM from
two urban sites in central and southern Europe, i.e. Mainz (MZ), Germany, and
Thessaloniki (TK), Greece. The total concentration of 11 NMAHs (∑11NMAH concentrations) measured in PM10 and total PM were
0.51–8.38 and 12.1–72.1 ng m−3 at the MZ and TK sites, respectively, whereas
∑7OPAHs were 47–1636 and 858–4306 pg m−3, and ∑8NPAHs were ≤90 and 76–578 pg m−3, respectively. NMAHs
contributed 0.4 % and 1.8 % to the HULIS mass at MZ and TK, respectively.
The mass size distributions of the individual substances generally peaked in
the smallest or second smallest size fraction i.e. <0.49
or 0.49–0.95 µm. The mass median diameter (MMD) of NMAHs was 0.10 and 0.27 µm at MZ and TK, respectively, while the MMDs of
NPAHs and OPAHs were both 0.06 µm at MZ and 0.12 and 0.10 µm
at TK. Correlation analysis between NMAHs, NPAHs, and OPAHs from one side and
WSOC, HULIS, sulfate, and potassium from the other suggested that fresh
biomass burning (BB) and fossil fuel combustion emissions dominated at the TK
site, while aged air masses were predominant at the MZ site.
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