Determination of Capsaicin and Dihydrocapsaicin in Capsicum (Capsicum annuum) Products by High Performance Liquid ChromatographyFluorescence Detection (HPLCFLD)
2019-09-10WenjuanZHENGLingtongHUDandanHUYuFANG
Wenjuan ZHENG Lingtong HU Dandan HU Yu FANG
AbstractSamples of nearsurface atmosphere dustfall and different pollution endmembers were collected in the urban area of Jining City. The element characteristics of the nearsurface atmosphere dustfall and pollution endmembers were analyzed systematically and the spatial distribution of the dustfall and its pollution sources were studied. The results showed that the contents of elements varied obviously in different pollution endmembers. The contents of As, Cd, Cu, F, Pb, S and Se within coal dustfall were the highest, higher than those in atmosphere dustfall and had great influences on the environment. The contents of Cd, Pb, Se, Zn, Hg and CaO within nearsurface atmosphere dustfall were affected by human activities to different degrees. Results of correlation analysis and factor analysis showed that Cd, Pb, Se and Zn mainly came from enterprise coal consumption, with a contribution ratio of 26.32%. The contents of the above four elements near chemical factories, steel factories and high populated regions were generally high, which was consistent with the spatial distribution of the coal pollution sources. CaO was related to traffic pollution, with a contribution ratio of 10.06%. Hg was mainly due to automobile emissions, with a contribution ratio of 8.12%. The contents of As, Cr, F and Ni within dustfall were seldom influenced by human activities and mainly came from soil sedimentation (natural sources), with a contribution ratio of 30%. The above four pollution sources (enterprise coal consumption, traffic pollution, automobile emissions and soil sedimentation) were the main sources of atmosphere dustfall in Jining City. The enrichment coefficients of As, Cr, F and Ni were smaller and the spatial correlations of the four elements were better, while the enrichment coefficients and variable coefficients of elements influenced by human activities, such as Cd, Pb, Se and Hg were larger, and the spatial distributions of these elements were consistent with those of the pollution sources.
Key wordsPollution endmember; Atmosphere dustfall; Enrichment degree; Factor analysis; Jining City
Received: September 10, 2018Accepted: November 27, 2018
Supported by Program of Ecological and Geochemical Survey in the Lower Reach of the Yellow River in Shandong Province (1212010310306).
Jierui DAI (1977-), male, P. R. China, senior engineer, devoted to research about agricultural geology and environmental geology.
*Corresponding author. Email: daijierui@126.com.
At present, urban environmental monitoring has been highly studied on total suspended particulates, aerosol (PM10, PM2.5), atmosphere dustfall and floating dust. There are also many studies on related aspects, while few people have done systematic research on nearsurface atmospheric dust. Nearsurface atmosphere dustfall is atmospheric dust at the average breathing height (1.5 m) of human body, which is a mixture of atmospheric particulate matter and surface dust[1]. With the rapid development of urbanization and industrialization, manmade sources have become the main sources of toxic and harmful elements in nearsurface atmosphere dustfall[2-5], which carries more complicated pollutants, including nitrogen oxides and hydrocarbons in addition to various heavy metals and organic pollutants. Nearsurface atmosphere dustfall not only affects peoples living environment, but also carries pollutants which would cause secondary pollution to soil, plants and water bodies after settlement, thereby endangering human health. Therefore, understanding the distribution characteristics and changing laws of urban nearsurface dustfall and studying the main pollution factors affecting dustfall are of great significance to the prevention and control of dust pollution, improvement of urban atmospheric environmental quality and guarantee of human health and urban construction planning.
General Situation of the Study Region
Jining City is located in the junctional zone between Taiyi low mountains and hills in south Shandong and the Huanghuaihai Plain in southwest Shandong. The geological structure belongs to the faultblock sunken area in southwest Shandong, North China region. The terrain is dominated by plain depressions, and high in the east and low in the west. There are mountains and hills in the east, and a flat Yellow River flood plain in the west. The central region of Nansi Lake (Nansi Lake is the general name of Weishan Lake, Nanyang lake, Zhaoyang Lake and Dushan Lake) which runs through from north to South. Jining City belongs to the zone of the warm temperate continental monsoon climate, with an average temperature in the range of 13.3-14.1 ℃ and an average annual precipitation in the range of 597-820 mm. The total area of the city is 10 685 km2, and the urban area is 1 262 km2.
Jining City is one of the three major industrial center cities of Shandong Province, which is the focus of the planning and construction of Shandong Province. It has been initially formed a relatively complete industrial system. With the rapid development of city modernization and industrialization in the past 30 years, Jining City and the surrounding area have set up a number of enterprises, such as chemical plants, chemical fiber factories, cement factories, brick factories, chemical fertilizer factories and brewery, etc. Building industry has developed rapidly over the past 10 years, the amount of vehicle increases sharply, and coal, industrial dust, road dust, vehicle exhaust dust and construction dust have a serious impact on the citys air quality. In recent years, many researchers have investigated soil environmental quality and air quality in Jining City[6-7], but no studies have been conducted on the distribution and pollution characteristics of heavy metals in the near surface atmospheric dust. Based on the study of the pollution source and pollution characteristics of near surface air dust in Jining City, correlation analysis and factor analysis were used to calculate the contribution of each source to the atmospheric dust, and the possible sources were discussed.
Sample Collection and Analysis
Pollution end sample collection
The distribution of industry, transportation and construction in Jining City were investigated in detailed. There were traffic dust, construction dust, coal dust and vehicle exhaust dust place points which are exhaust emissions and serious pollution. Each kind of dust was sampled at 6 points. Traffic dust was sampled in urban areas with large traffic flow. Building dust samples were collected in large scale urban construction sites. Coal dust should be taken into account when sampling the dominant wind direction, and samples were collected in the downwind area of coal enterprises. Floating dust was collected from 1.5 to 2.0 m around the upper part of the artificial platform and the building. Coal dust samples can also be collected on the inner wall of chimney and surrounding. Automobile exhaust dust sampling points were distributed in the large parking lot, bus station and gas station: exhaust dust was directly in scraped in the automobile exhaust pipe, vehicle exhaust dust of the same type was merged into one sample, and car types and the type of gasoline were recorded in detailed. The above samples were between 20 to 50 g, which can meet the requirements of the quantity of analysis and preservation.
Nearsurface atmospheric dust collection
The nearsurface atmospheric dust samples were collected by the grid pattern acquisition method (1∶5 million topographic map), and the sampling density was one sample per square kilometer. A portable GPS was used to determine its geographical coordinates, and the fixed point error was not more than 1 mm on the graph, which meant the actual distance was not more than 50 m. The samples were collected in the middle and lower layers, mainly flat roof room, windows of residential buildings, poles, trees, bus stop, etc., by sweeping with a brush and holding the dust with a clean plastic bag. Sampling should be away direct pollution sources (such as industrial pollution, civil coal, paint, etc.) as far as possible. The method of multipoint and equal volume mixing was used to collect 306 samples per point, which was about 20 g. In order to compare with native soil, the surface soil samples were collected at the same point of dust in the green belt or park and so on. The 0-20 cm soil was collected vertically after removing surface debris when ensuring uniform collection, and animal and plant residue, gravel and fertilizer mass were discarded. The sampled soil was put into a clean bag, and the original sample weight was greater than 200 g. Soil samples were air dried and crushed, and sieved with a 20 mesh nylon sieve, and 80 g was taken to laboratory for analysis.
Fig. 1Sampling positions of the pollution endmembers and nearsurface atmosphere dustfall in Jining
Sample analysis
The pollution endmember samples were analyzed for such 19 indicators as As, Cd, Co, Cu, Cr, F, Hg, Mn, Ni, Pb, S, Ti, Zn, Se, Na2O, Al2O3, CaO, K2O and MgO. Nearsurface atmospheric dust and soil samples were analyzed for such 10 indicators as As, Cd, Cr, Hg, Ni, Pb, Zn, F, Se and CaO.
The sample test was completed by Shandong Institute of Geological Survey. The indicators such as Co, Mn, Ni, Zn, MgO and CaO were determined by plasma emission spectrometry after digestion with HF+HNO3+HClO4+aqua regia. During the determination of indicators such as Pb, Cr, Ti, Al2O3 and K2O, the sample powder was pressed under 35 t pressure to pieces and then analyzed by Xray fluorescent spectrometry. As to indicators such as As, Hg and Se, the sample was digested with 1+1 aqua regia into a boiling water bath, and subjected to redox treatment by adding potassium permanganate and oxalic acid, and then analyzed with an atomic fluorescence spectrometer. The Cd element was determined by digesting with HF+HNO3+HClO4+ aqua regia, adding matrix modifier, and analyzing by graphite furnace atomic absorption spectrometry. For the determination of F element, the sample was melted with NaOH at 700 ℃, extracted with water, and determined with an F ion selection electrode on an ion activity meter after the addition of an ion intensity regulator. S element was determined by burning the sample with a tube furnace burn and analyzing by iodometric method. Various monitoring methods such as standard sample, code sample and monitoring sample were applied, to guard the analysis quality, and the testing quality passed the test by the expert group from China Geological Survey Bureau.
Result and Discussion
Characteristics of pollution endmember element contents
As shown in Table 1, the contents of most indicators from building dust and coal combustion were mostly stable, while the variable ranges of indicator contents from automobile exhaust were larger, for example, the maximum of Zn content was 34.67 times of the minimum in the automobile exhaust, and the maximum of Ti was 30.18 times of the minimum. These conditions might be connected with automobile performance and fuel quality, but the mean data still could reflect the overall level of element pollution from automobile exhaust.
Compared with nearsurface dust, the contents of all elements from coal combustion were slightly higher (the specific values were greater than 1.2). Among them, the content of Se was 502.54 times of dustfall; the content of As was 9.61 times of dustfall; and the contents of other elements were 1.33 (Cr)-8.33 (Cd) times of dustfall. In traffic dust, except Cr and Ni, other elements were 1.42 (F)-7.11 (Zn) times of dustfall. In building dust, the contents of Pb, CaO, Se, As and Zn were slightly higher. Among them, the content of Pb was 11.25 times of dustfall, and other elements were 1.63 (Zn)-5.11 (Cao) times of dustfall. In automobile exhaust, the content of Hg was 3.11 times of dustfall, and Zn, Se, Ni and Cr were 1.34 (Cr)-1.78 (Zn) times of dustfall. All the data indicated the elements from the pollution endmembers can enter atmosphere and speed up accumulate of heavy metals in dustfall.
Jierui DAI. Geochemical Characteristics and Pollution Source Identification of the Nearsurface Atmosphere Dustfall in Jining City, Eastern China
Table 1Statistics of the contents of pollution endmember elements in Jining
Indicators
Traffic dust
Content range Mean
Building dust
Content range Mean
Coal dust
Content range Mean
Automobile exhaust dust
Content range MeanAtmosphere dustfall
As13.53-20.0916.0214.48-22.8819.1313.01-222.0582.402.48-9.046.048.57
Cd0.71 -1.741.260.12-0.340.200.36-2.611.500.06-0.230.150.18
Co11.33-13.5411.988.11-14.089.9714.31-27.9922.152.46-16.706.29--
Cr64.01-91.1876.8938.99-80.8251.9175.01-123.5092.3736.06-156.3292.8969.20
Cu49.88-90.4872.3027.27-190.6273.3576.39-288.74164.7218.99-143.3877.83--
F533-940669272-451384336-95113 34480-178134471.00
Hg335-722460.847-11869.4274-830498240-840570183.00
Mn446-518487259-1472681220-130558745-135104--
Ni22.11-29.4926.529.64-26.3916.1533.24-99.4163.237.70-201.0061.8727.14
Pb116.3-268.0172.341.0-1 231.2272.847.1-613.4362.16.0-17.511.332.20
S0.40-0.610.500.23-0.530.390.46-12.643.581.36-2.251.87--
Se2.21-5.493.361.68-5.892.8528.85-852.07296.501.83-4.963.620.59
Ti0.35-0.390.370.19-0.260.210.31-0.720.440.003-0.0850.022--
Zn307-1 81342559-292140158-46530637-129767286.10
Al2O310.26-11.3110.799.07-11.089.759.59-23.7814.830.18-0.660.38--
CaO9.62-19.1317.0713.88-27.0118.154.05-14.479.000.43-1.580.983.55
K2O1.53-1.761.651.50-2.091.820.61-1.170.840.04-0.110.06--
MgO1.43-2.061.751.06-2.711.570.05-0.530.200.07-0.220.13--
Na2O1.60-1.821.682.10-2.332.240.78-1.531.240.08-0.170.13--
The content of Hg should be multiplied by 10-9; the contents of S, Ti, Al2O3, CaO, K2O and MgO should be multiplied by 10-2; the contents of remaining elements should be multiplied by 10-6; and -- means not counted.
The comparison of different pollution endmember elements are shown in Fig. 2. For convenience of comparison, Fig. 2 adopts standardized mapping, that is, the element contents were multiplied by 10n (n is an integer), and the data results were controlled within 25.
The contents of elements were very different between different kinds of pollution endmembers. The contents of As, Cd, Co, Cu, F, Ni, Pb, S, Se, Ti and Al2O3 were higher than others in the coal combustion dust. The content of MgO was the highest in traffic dust, and in addition, the contents of Cd, Co, Hg, Ti, Zn, CaO, K2O and Na2O had a high level. The contents of Hg, Cr and Zn were the highest in automobile exhaust. The content of Hg was 1.14 (coal combustion dust)-8.21 times(building dust) of others, while the contents of As, Cd, Co, F, Mn, Pb, Ti and oxide were minimum in all kinds of endmember dust. The elements showed a polarizing trend in building dust. Compared with other endmember, the contents of Cr, Hg, Ni, S, Se and Zn were the lowest. The contents of Mn, CaO, K2O and Na2O were the highest.
On the whole, coal combustion dust (As, Cd, Co, Cu, F, Ni, Pb, S, Se, Ti and Al2O3) had the highest impact to the environment. Automobile exhaust (Hg, Cr, Zn, S and so on) and traffic dust (Cd, Co, Hg, Ti, Zn and oxide) were in the middle, while building dust (Mn, CaO, K2O and Na2O) had the lowest impact to environment. Meanwhile, the element combination can deed symbolic element of different kinds of pollution endmembers.
Fig. 2Comparison of the contents of different pollution endmember elements in Jining
Characteristics of atmospheric dust element contents
As shown in Table 2, the elements in the nearsurface atmospheric dust and in the soil were all in significant positive correlation at the 0.01 significant level, indicating that the dust and the soil had a close relationship.
The content ranges of As, Cr, Ni and F in dust changed slightly, with the coefficients of variation less than 0.4, and the correlation coefficients of the corresponding elements in the soil were greater than 0.4. The scatter distribution was approximately linear and the contents in soil were almost equal or slightly higher (Fig. 3). It can be believed that the above elements were not enriched at all relative to the soil and mainly from soil dust. Although Pb and Zn in dust were similar to those mentioned above elements, That is, they all had the characteristics of large correlation coefficients, almost equal contents and small coefficients of variation, seeing from the comparison of geochemical map of Pb element between dust and surface soil (Fig. 4), Pb abnormalities also occured in urban areas. The content of Pb in dust was more than 40×10-6, which was consistent with the spatial distribution of urban enterprises, and this range was slightly larger than the soil. This fully reflected the human activities leading to lead pollution and zinc pollution in dust, and affected the distribution of related elements in soil. Although the average content of Hg in dust was close to the soil background value (the enrichment coefficient was 0.92), the coefficient of variation was as high as 1.35. It showed that the distribution of Hg element in the dust was uneven, and the mercury pollution was especially serious in densely populated urban areas.
Compared with the soil background value, the contents of Se, Cd and CaO in dust were significantly high and the enrichment degrees of elements from high to low in turn were Se (2.07), CaO (1.67) and Cd (1.32). Meanwhile, the correlation coefficients of the corresponding elements in soil were less than 0.3. As shown in the scatter plot of Se, Cd (Fig. 5), the distribution pattern shows that there were a few extremely high content points in dust. These high content points might be caused by the superposition of artificial point source pollution. Through the above analysis, it could be seen that Hg, Se, Cd, Pb, Zn and CaO in dust may be affected by human activities. However, the elements of As, Cr, Ni and F may mainly come from soil dust (natural sources).
Table 2Statistics of the contents of the nearsurface atmosphere dustfall elements in Jining
ElementContent rangeMeanMidvalueStandarddeviationCoefficientof variationSoil backgroundvalue EnrichmentcoefficientCorrelationcoefficient
As3.07-17.798.578.312.440.298.561.000.343
Cd0.08-0.760.180.160.090.490.141.320.209
Cr33.03-186.9869.2067.5816.970.2574.250.930.342
F146-781471459104.200.225480.860.388
Hg16-2 188183110248.221.351990.920.519
Ni12.92-46.9627.1425.836.520.2432.990.820.514
Pb14.01-99.6232.2129.7010.520.3331.291.030.620
Se0.14-6.460.590.390.621.050.292.070.208
Zn42.4-301.886.177.334.280.4084.01.020.345
CaO1.19-29.073.552.562.800.792.161.640.295
The content of Hg should be multiplied by 10-9; the content of S should be multiplied by 10-2; and the contents of the remaining elements should be multiplied by 10-6; the number of statistical samples is 306, and at the confidence value α=0.01, the relevant critical value is about 0.207.
Fig. 3Scatter diagrams of As and Ni in nearsurface atmosphere dustfall and in surface soil in Jining
A: Geochemical distribution of Pb in near-surface atmosphere dust-fall; B: geochemical distribution of Pb in surface soil.
Fig. 4Geochemical distribution of Pb in nearsurface atmosphere dustfall and in surface soil in Jining
Fig. 5Scatter diagrams of Se and Cd in nearsurface atmosphere dustfall and in surface soil in Jining
Correlation analysis between elements in dust
The correlation coefficient table (Table 3) of the contents of elements in dust in Jining City shows that the correlation between nonenriched (nonpolluting) elements which may originate from soil particles such as As, Cr, Ni and F and had enrichment coefficients less than 1 was better. The correlation coefficients between Ni and As, Cr and F and that between Cr and F were all above 0.55. Specifically, the correlation coefficients were 0.556, 0.776, 0.744 and 0.579, respectively. The correlation coefficients between As and F and Cr were 0.448 and 0.450, respectively.
Table 3Correlation coefficients of the element contents in nearsurface atmosphere dustfall in Jining
ElementAsCdCrFHgNiPbSeZnCaO
As1.000
Cd0.1301.000
Cr0.450-0.1031.000
F0.448-0.1610.5791.000
Hg0.0860.192-0.013-0.0441.000
Ni0.556-0.1530.770.744-0.1211.000
Pb0.2590.4400.004-0.0410.184-0.0091.000
Se0.1080.216-0.128-0.2010.125-0.0680.3771.000
Zn0.3200.4540.0610.0160.1660.10.6060.3811.000
CaO0.0080.181-0.393-0.223-0.001-0.3980.1290.2330.3861.000
The correlation between enriched (polluting) elements which may originate from manmade pollution such as As, Cr, Ni and F with enrichment coefficients greater than 1 was general. Among them, the correlation between elements of Cd, Pb, Se and Zn were relatively high. The correlation coefficient between Pb and Zn was 0.606. However, the correlation coefficients between other elements were between 0.216 (Se and Cd) and 0.454 (Cd and Zn). CaO was negatively correlated with Cr, F, Ni and other elements and the correlation coefficients were below -0.4. This showed that the sources of these pollution elements had a certain correlation, but the correlation was less obvious than the nonpollution elements, which might be because that the sources were more complex. However, the correlation between Hg and other elements was poor (the correlation coefficient was less than 0.2), and the main source was obviously different from other elements.
Analysis of the contribution of polluted end to dust
In order to analyze the relationship between elements in dust in Jining City and further determine their sources and control factors, principal component analysis of data was carried out by SPSS software and an initial factor load matrix was obtained. In order to eliminate the influence of the contents of different elements on the order of magnitude, the maximum variance orthogonal rotation reduction was used to obtain the factor load matrix. It could be seen from Table 4 that the cumulative contribution rate of the 4 factors was 74.50%, that is, 4 types of pollution sources were selected.
Table 4Factor load matrix of the elements in nearsurface atmosphere dustfall in Jining
Element variable
Factor load
Factor 1Factor 2Factor 3Factor 4
As0.7270.2010.2040.046
Cd-0.1440.889-0.007-0.029
Cr0.806-0.019-0.2990.042
F0.823-0.08-0.108-0.101
Hg-0.0800.194-0.1510.817
Ni0.933-0.055-0.143-0.023
Pb0.0730.6700.1460.176
Se-0.0170.6060.2060.206
Zn0.1900.7030.2790.103
CaO-0.2760.1690.794-0.167
Characteristic value3.002.631.010.81
Contribution rate∥%30.0026.3210.068.12
Cumulative contribution rate∥%30.0056.3266.3874.50
In factor 1, As, Cr, F and Ni had larger factor coefficients. The critical value of correlation coefficient was 0.207 at the 0.01 confidence level. Therefore, the 4 elements are significantly correlated with the first factor. The previous studies showed that for F, Ni and Cr as the main elements of coal combustion emissions, their average contents in burning coal dust were up to 3 344×10-6, 63.23×10-6 and 92.39×10-6, respectively. Se was the indicator element of coal combustion[8-9], and the average content was 269.50×10-6. If Se and these 4 elements As, F, Ni and Cr appear simultaneously, the 4 elements may be derived from burning coal. There was Se without As, F, Ni and Cr, so coal was not the main source of the 4 elements. The correlation coefficients of Se and F, Ni and Cr in study area were -0.201, -0.068 and -0.128, respectively. The correlation between Se and As was also poor (the correlation coefficient was 0.108). In addition, the contents of the 4 elements in dust were close to or slightly smaller than the soil values. There was significant positive correlation between them and they had the same source. It could be seen from the above analysis that the first factor represented the natural source, that is the settlement of soil dust from local or adjacent areas and the contribution rate was 30%.
Factor 2 was significantly related to Cd, Pb, Se and Zn. The correlation analysis showed that Cd, Pb, Se and Zn in dust in Jining city may have the same source. Compared with the soil background values, they all had a higher content or greater coefficient of variation. From the spatial distribution of element content, it could be seen that Cd, Pb, Se and so on were related to coal combustion activities. It was also found that the dust sample points which were near the urban central, iron and steel plants and chemical plants had the highest content of Cd (0.76×10-6) and higher contents of Se (4.16×10-6 ) and Zn (252×10-6). Therefore, it was proved that these elements were mainly derived from industrial coal. It was considered that coal combustion was the second pollution factor, and its contribution rate was 26.32%.
According to relevant research data[10-12], Pb is a tracer element of automobile exhaust emissions. However, this research showed that in automobile exhaust dust the content of Pb was the lowest. In dustfall, the Pb was controlled by F2 factor representing coal source. This shows that with the compulsory use and popularization of unleaded gasoline, industrial coal has gradually become a major source of Pb in atmospheric dust.
Factor 3 was significantly related to CaO and had a relatively large factor coefficient with Zn, so we can infer that the third factor came mainly from the second traffic pollution. The traffic dust was collected in the dust of heavy traffic roads and was a mixture of soil particles and automobile exhaust dust. The previous analysis showed that Zn was the main element of coal combustion emissions. CaO had the highest content in construction dust and the soil also contained a certain amount of CaO. The correlation coefficient of two elements of different sources was 0.386. It was concluded that the two elements in dust came from the second polluted traffic dust. In addition, the ratio between CaO and Zn can also be confirmed. CaO/Zn in atmospheric dust was 412.3, which was close to traffic dust (CaO/Zn was 401.6), and far from the construction dust (1 296.4), burning coal dust (294.1) and exhaust dust (14.6). Therefore, the third factor represented the source of traffic dust and the contribution rate was 10.06%.
Factor 4 was only significantly related to Hg. Cars and coal will produce a certain concentration of Hg, but the correlation between Hg and coal characteristic elements such as As, Se and Pb and so on was very poor. In view of the above reasons, it was concluded that PC4 was automobile emission factor, and the contribution rate of atmospheric dust was 8.12%.
Spatial distribution characteristics of atmospheric dust elements
The spatial interpolation method of DTM module of Map GIS software was used to make the element distribution map. It was found that the contents of elements in dust were different in different regions of Jining. From the F2 factor score chart (Fig. 5), it could be seen that the second factor high score area associated with elements such as Cd, Pb, Se and Zn was in good agreement with the distribution scope of urban enterprises. This fully reflects the consistency of the geographical distribution of the pollution sources. Especially, the scores were the highest in the chemical plants, steel plants and densely populated urban areas. The highest score was far higher than that in other parts of Jining, which was related to the longterm burning of coal by residents and enterprises. Although influenced by regional soil dust, the F1 (As, Cr, F and Ni) scores had no significant differences in different regions, but were relatively higher in the western brick factory, the eastern chemical plant and the steel plant. This might be related to pollution emissions in the region.
The average content of CaO in dust near Jining bus station was 8.4%, and the maximum value was 20.4%. Meanwhile, the content decreased gradually around the center of the station, it was related to the large traffic flow in this area. The high content area of Hg element in dust was consistent with the population density area in urban area. In addition, the content was the highest in the bus station and along the main roads in the city, and in other parts of the city, the content was relatively stable, and low in suburban the content.
Fig. 6Spatial distribution of F2 factor scores in nearsurface atmosphere dustfall in Jining
Conclusions
The contents of elements in different pollution ends were obviously different. The contents of As, Cd, Co, Cu, F, Ni, Pb, S, Se and other elements in coal dust were the highest. Among them, the contents of Se, F and As were 4 times more than other end dust. In coal dust, the content of Se was 81.91 times of that in tail gas and 104.04 times of that in building dust. Burning coal dust had a great influence on environment. However, most of the elements in the building dust were the lowest among all the pollution ends and only the content of oxides and Mn element were high, so building dust had little impact on the environment. The effects of other end dust on the environment were in the middle. In the past, Pb was a tracer element for automobile exhaust emissions, but with the popularity of the compulsory use of unleaded gasoline, industrial coalfired emissions have gradually replaced automobile exhaust as the main source of Pb in atmospheric dust.
The elements of As, Cr, F and Ni in the dust which are not affected by human activities were more consistent in spatial distribution, and had better correlation coefficients and smaller enrichment coefficients. The contents of these elements in dust were mainly affected by soil dust deposition (natural source). However, the elements of polluting Cd, Pb, Se, Zn, Hg and CaO (indices) which are influenced by human activities to different degrees had greater enrichment coefficients or coefficients of variation, the correlation was poor, and the spatial distribution was consistent with the pollution source. Studies have shown that Cd, Pb, Se, and Zn mainly originate from coal combustion enterprises. CaO related to traffic pollution and Hg mainly came from vehicle exhaust emissions. The above 4 kinds of pollution sources were the main sources of dust in Jining. Specifically, the contribution rates of soil dust, coal dust, traffic dust and exhaust dust were 30%, 26.32%, 10.06% and 8.12%, respectively.
The results of this study show that that the content analysis, correlation analysis and factor analysis of the elements of different pollution ends and atmospheric dust are effective methods to indicate the sources of pollution elements in urban atmospheric dust. In view of the current situation in Jining, the prevention and control of coalburning pollution is an important task. With the rapid growth of car ownership, automobile exhaust pollution cant be ignored.
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