Seasonal Trends of Polycyclic Aromatic Hydrocarbons in Particulate Matter at an Urban Site in Beijing, China ()
1. Introduction
Industrialization and urbanization have promoted socio-economic development. This has, however, led to variety of environmental problems in urban areas, including contamination by polycyclic aromatic hydrocarbons (PAHs) via various pathways [1]. Airborne PAHs, either in gas or particle phases, are found to have a direct impact on human health [2]. PAHs are resistant to degradation and bio-accumulate through the food chain, thus they also may pose threat to human health over a long period. Considering the high toxicities of PAHs, it is necessary to study the concentrations, profiles and sources of PAHs in the particulate matter (PM). PAHs come from two main sources. Natural PAHs are mainly from volcanic eruptions and natural fires. Anthropogenic PAHs are mostly generated during the combustion of carbonaceous materials such as coals, gasoline and diesel [3]. Previous studies suggested that PAH concentrations increased significantly in the urban PM parts since the 1990s [4]-[7].
Beijing, the capital city of China, located in the Northern China, is a fast developing city with over 1000 years of history. PAH pollution in the particulate matter of Beijing has been reported [8]. The city consists of 14 administrative districts. As one of the busiest traffic routes in Beijing, the Third Ring Road built in the 1980s crosses five central districts, named after Haidian, Chaoyang, Chongwen, Xuanwu and Fengtai. The five districts contain the majority of the commercial, industrial and traditional areas of Beijing. Both districts of Xuanwu and Chongwen comprise the old historic centers, while Haidian, Chaoyang and Fengtai, located in the northern, eastern and southern region, and are the centers for high technology, central business and industrial district, respectively. The PM near the road was the focus of this investigation as they serve as an important reservoir of PAHs generated by traffic emission [9]. The chemical analysis of PM samples can, therefore, provide a useful and convenient initial measure of environmental quality. The aims of this work were to: 1) determine individual concentrations of PAHs profile in the PM samples including PM10 and PM2.5 collected from the Third Ring Road, 2) identify seasonal variations of PAHs to track their possible influencing factors.
2. Methods and Materials
2.1. Sampling Site and PM Mass Measurement
Influenced by the summer monsoon, Beijing experiences cold, relatively dry winter, hot and humid summer. The sampling site was located near a busy traffic line in Beijing (116˚18'10''8E, 39˚56'50''7N) (measured by GPS Etrex Vista HCX, made by GARMIN). Sampling equipments were set up on the roof of an office building with a height of 30 m aboveground and a distance about 30 m from the road/traffic. This is a very busy ring road with 6 fast tracks and 4 voeux roads; with 230 - 270 vehicles at the speed about 50 km/hour passing through per minute in the morning rush hour. 24-h PM10 and PM2.5 were collected onto 90 mm diameter quartz microfiber filters (QMA, Whatman) at a flow rate of 100 L/min, using the Smart TSP Volume Air Samplers (TH-150A type, made by Wuhan Tianhong Instrument Co.,Ltd.), equipped with different PM head for PM10 and PM2.5 respectively. The filter was replaced at 10:00 a. m. Beijing time daily through the whole sampling period, and the measurement was carried out for one month every season. In detail, samples were collected from June 10 to July 10 in summer 2009, from September 10 to 30 in autumn 2009, from December 1 to 31 in winter 2009, and from March 1 to 31 for spring of 2010.
Filters were weighed using a balance (CP225D, with accuracy of 0.01 mg, made in Sartorius, Germany), and PM mass was calculated as the mass differences before and after sampling at unit sampling volume. Filters were heated for 4 hours at 550˚C and preserved in desiccators with humidity of 34% for 24 hours before pre-sampling weighing. After sampling, filters were kept in desiccators for 24 hours before re-weighing. During the weighing procedure, temperature was controlled at 20˚C by air conditioning. Filters were then cut into quarters using stainless steel cutter for subsequent component analysis.
2.2. Sample Analysis
All the organic solvents were high performance liquid chromatography (HPLC) grade, purchased from Fisher (Fair Lawn, NJ, USA). ‘Superclean’ silica gel solid phase extraction columns (6 mL, 500 mg) were purchased from Supelco Inc. (Bellefonte, PA, USA). The standard with 16 PAHs (EPAM-610, 1 mL, 0.1 mg/mL in 1: 1 methanol: dichloromethane) and the 2D-labelled surrogate standards (EPA M-525-IS, 1 mL, 2.0 mg/mL in acetone), which included acenaphthylene-d10, chrysene-d12, perylene-d12 and phenanthrene-d10, were purchased from Accustandard Inc. (CT, USA).
The extraction method was as follows. Prior to ultrasonic extraction with n-hexane and dichloromethane (1: 1, v/v), the samples were spiked with 2D-labelled surrogate standards. The extracts were completely dried in a rotary evaporator and subsequently dissolved in 10 mL of hexane. Then, samples were drawn through the activated column through the clean column by gravity. Then, dichloromethane was used to elude the PAHs for three times (6 mL each time). The eluents was concentrated to 0.5 mL under a gentle nitrogen gas flow before being injected into the GC-MS.
PAHs were quantified on a Varian 350 gas chromatography coupled with Varian 240 mass spectrometer with electron impact ion (EI) source. Helium was chosen as carrier gas with a constant flow of 1.0 mL/min. The extract was injected into the injector with splitless mode, and separated on a DB-5MS fused silica capillary column. The electron emission energy was set at 70 eV. The source and ion trap temperature was set at 280˚C and 220˚C, respectively. The oven temperature programs were as follows: started at 50˚C retaining for 2 min, first ramped to 200˚C at speed of 10˚C/min, second ramped to 260˚C at 2˚C/min, and finally ramped to 260˚C at 5˚C/min, kept for 4 min.
2.3. Quality Control
Analytical methods were checked for the precision and accuracy. All the samples were analyzed three times to obtain the average level. Replicate analyses gave an error between ±15%. The recoveries were checked by analyzing soil and needles samples spiked with known amounts of labeled PAHs. The average recoveries of surrogates were 73.8% (acenaphthylene-d10), 92.5% (chrysene-d12, perylene-d12) and 83.2 (phenanthrene-d10). The spiked test showed the recoveries of 16 PAHs were from 60.2% to 114.3% with the RSD from 5.6% to 15.4%.
2.4. Data Analysis
The measured data was processed by SPSS 18.0 and excel software.
3. Results and Discussion
3.1. Total PAHs in PM10 and PM2.5
PM10 and PM2.5 samples collected from the Third Ring Road in Beijing, each with 82 in total, were analyzed PAHs concentrations. The concentrations descriptions of 16 individual PAHs specie with their abbreviations are listed in Table 1. Individual PAH concentrations at traffic sites ranged from n.d. (below the detection limit, 0.2 ng/m3) to 558.49 ng/m3 for benzo(b)fluoranthene (BbF) in PM10 samples and from n.d. (below the detection limit) to 177.93 ng/m3 also for BbF in PM2.5 samples. Yearly average PAHs concentration in PM10 is 126.16 ng/m3, less than that measured as 164.6 ng/m3 in Xuzhou, a Chinese city in the middle of the country [10]. Meanwhile, yearly average PAHs concentration in PM2.5 is 107.18 ng/m3, much less than 712.4 ng/m3 measured in a coal producing northeast Chinese city of Fushun [11].
Table 1. Summary of PAHs concentrations in PM samples at an urban roadside site in Beijing (ng/m3).
n.d.: below the detection limit (0.2 ng/m3); Min: Minimum; Max: Maximum.
3.2. Seasonal Variations of PAHs in PM Samples
As shown in Figure 1 and Table 2, for PM10 samples, the concentrations of phenanthrene (PA), pyrene (Pyr),
Figure 1.Seasonal variation of PAHs in PM10 and PM2.5. The same letter means no significant difference among the sub-groups.
Table 2. Seasonal variation of PAHs in PM10 and PM2.5 samples (ng/m3).
Notes: S.D. refers to standard deviation.
indeno(1,2,3-cd)pyrene (IND), fluoranthene (FL), dibenzo-(a,h)anthrancene (DBA), chrysene (CHR), benzo(k)- fluoranthene (BkF), benzo(b)fluoranthene (BbF), benzo(a)-pyrene (BaP), benzo(a)anthracene (BaA) and acenaphthylene (AcPy) were much higher in winter than in other seasons (p < 0.05), whereas the concentration of naphthalene (Nap) was higher in summer than in other seasons. Concentrations of fluorene (Flu) and benzo (g,h,i) perylene (BghiP) were higher in spring and winter than those in summer and autumn. In addition, no significant seasonal trends of anthracene (Ant) were found. For PM2.5 samples, the concentrations of PA, Pyr, IND, FL, DBA, CHR, BkF, BghiP, BbF, BaP, BaA were much higher in winter than in other seasons (p < 0.05). Similar to that in PM10, the concentration of Nap in PM2.5 was also higher in summer than in other seasons. Otherwise, the concentrations of Flu, Ant, acenaphthene (Acp) and AcPy did not show significant seasonal variations (Figure 1 and Table 2).
3.3. Source Apportionment of PAHs
3.3.1. Principal Component Analysis (PCA)
Results of PCA give four and five significant PCs (eigenvalues > 1), which explains 83.1% of the variation for PM2.5 data (43.5%, 17.1%, 14.8% and 7.8%, respectively) and 85.4% of the variation for PM10 data (43.6%, 18.2%, 9.7%, 7.6% and 6.3%, respectively). As shown in Table 3, four or five factors of PAH congeners can be observed, corresponding to the different carbon rings, from di- to six cyclic-rings molecular.
3.3.2. Ratio Analysis Methods
According to previous opinion [12], both PAHs of PM2.5 and PM10 in winter mainly originated from fossil fuels burning based on the ratio of Ant/(Ant + Phe) < 0.3, while in other three seasons, Ant/(Ant + Phe) > 0.3, implying PAHs were possibly from biomass fuel combustion (Table 4). Pankow [13] thought that PAHs originate from combustion source at BaA/(BaA + Chr) > 0.35,mainly from oil at < 0.2, and from both at 0.2 - 0.35. Ac-
Table 3. Principal component analysis of PAHs in PM samples.
Table 4. Ratio between typical individual PAHs concentrations.
cording to this, PAHs of PM10 in autumn and winter, together with PAHs of PM2.5 in autumn were sourced from both combustion and oil, while PAHs of PM10 in summer and spring, together with PAHs of PM2.5 in summer, winter and spring were from combustion. PAHs in both PM10 and PM2.5 were from coal combustion based on BaP/BghiP of 0.9 - 6.6 in all seasons except autumn, when the BaP/BghiP ratio was even less than 0.3 - 0.44, a traffic source range [14]. Based on the opinion of Kavouras et al. [15], the Fla/(Fla + Pyr) of PM10 and PM2.5 in this study is around to 0.4, representing for oil source in spring and winter. In addition, IcdP is a marker of diesel combustion and could tell the type of vehicle fuel [14]. IcdP/BghiP value near 0.22 implies PAHs sourced from gasoline combustion, 0.50 from diesel and 1.30 from kerosene. In this study, PAHs in autumn is between 0.22 to 0.50, implying mixed sources of gasoline and diesel. While in winter, IcdP/BghiP value is much higher than 1.30, implying other PAHs sources involved, which agrees with fossil fuels combustion source in winter.
4. Conclusion
In this study, individual PAHs concentrations in PM samples at an urban roadside site in Beijing were analyzed through seasons. The results show that the inputs of potentially toxic contaminants increased because of rapid economic development. Seasonal variations of PAHs compounds indicated 68.7% individual species of PAHs concentrations in winter were higher than those in other seasons. In contrast, Nap concentrations in both PM10 and PM2.5 were highest in summer, but the source is uncertain. In addition, four and five significant factors were identified to influence the variations of PAHs concentration in PM10 and PM2.5, respectively.
Acknowledgements
This work was supported by the Natural National Science Foundation of China (No. 41175104, 41475133 and 41305110).
NOTES
*Corresponding author.