Abstract
In order to study the spatiotemporal variations characteristic of water quality and potential pollution sources of Qujiang River, the water quality data of twelve water quality parameters at three monitoring sections (Tuanbaoling, Baita, and Sailong) from 2015 to 2019 were analyzed by using comprehensive pollution index (CPI) and multivariate statistical techniques (MST). The water quality parameters of Qujiang River basically meet the class 3 value of environmental quality standards for surface water (GB3838-2002, China). CPI varies from 0.62 to 1.06 and the water quality is characterized by slight pollution at the three monitoring sections. Cluster analysis (CA) results show that the months can be divided into three groups on the basis of similarities of the water quality characteristics: Group 1 (dry season), which includes January-April and November–December; Group 2 (flood season), that is, July; Group 3 (flat season), which consists of May–June and August–October. Principal component analysis (PCA) results identify four principal components (PCs) for the dry season and flood season, and five PCs for the flat season, thus explaining 58.23%, 82.94%, and 73.23% of the total variance, respectively. The results of the independent sample t-test show significant differences among the pH, Permanganate index (CODMn), Ammonia nitrogen (NH3–N), Total nitrogen (TN), Fecal coliform (F.coli), and (Flow) Q in the three monitoring sections. Moreover, the pollution is more serious in Baita than Tuanbaoling and Sailong Section and the main problem in the Qujiang River is the high water organic and nitrogen nutrient pollutant content. Hence, monitoring and protection need to be strengthened in the Baita section of Qujiang River.
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Introduction
Rivers are important freshwater resources used for domestic water, agricultural irrigation, and industrial purposes, the water quality is related to the safety of domestic water for coastal residents (Vega et al. 1998; Razmkhah et al. 2009). The water quality is not only affected by natural factors such as precipitation and land use type, but also by human activities such as industrial wastewater and domestic sewage discharge. It is well known that rivers have heavily polluted recently because of intensification of industrial and agricultural activities and the increase of population density (Nakagawa et al. 2019; Shao et al. 2020). The industrial and domestic wastewater as well as agricultural were discharged into rivers with surface runoff, atmospheric deposition, and land surface erosion processes (Qiu et al. 2017; Gurjar et al. 2019). At the same time, these pollutants undergo physicochemical and biological reactions in river water, river water quality has seasonal and regional characteristics. Therefore, it is essential for effective river management to monitor and assess the river water quality regularly (Bo et al. 2009).
At present, river water quality evaluation methods include single factor index (SFI) method, Nemero index method, artificial neural network (ANN), comprehensive pollution index (CPI) method, etc. (Xu et al. 2022; Zhou et al. 2020; Kouadri et al. 2021). Among them, the single factor index evaluation result is conservative, but it can accurately identify the main pollution factors and water quality categories. The comprehensive pollution index is proposed on the basis of the single factor pollution index method, which is an important method to evaluate water pollution and can evaluate the water pollution status comprehensively and comprehensively. Scholars at home and abroad have made in-depth evaluation on the water quality of the basin by using the comprehensive pollution index method. Zhang et al (2021) found that 7% of the five rivers in Baihua Lake Basin were seriously polluted in three periods using the comprehensive pollution index method, and CODCr, BOD5, NH3-N and TP were the main pollution sources. Bai et al. (2020) found that the comprehensive pollution index has fluctuated in the past 30 years (1988–2016) of Baiyangdian and water quality was the worst in 2015. Taking into account the spatiotemporal changes of river water quality, regularly monitoring rivers is necessary to evaluate their water quality reliably. These monitoring programs usually collect a large number of data sets which is complex to understand. Researchers found that multivariate statistical techniques (MST) can effectively simplify the data and obtain the spatiotemporal characteristics of water quality. Varol et al. (2012) applied multivariate statistical techniques to evaluate the spatiotemporal variations and identify the main parameters affecting the change of water quality of dam reservoirs in Tigris River Basin. Yang et al. (2020) applied cluster analysis (CA) and discriminant analysis (DA) to study the spatiotemporal variations and obtain the main problem in the Panzhihua section of the Yalong River is high water organic pollutant content. Therefore, multivariate statistical technique is an effective method for evaluating water quality characteristics.
Qujiang River, also known as Quhe, is the largest tributary on the left bank of Jialing River. It is the main source of water supply for urban domestic water and industrial and agricultural water, especially in the two sides of the main stream and the tributaries of Zhouhe River Basin, where agricultural production is developed. The water quality of the area is related to the water safety of the coastal residents as well as the growth of crops along the river. At present, the research on Qujiang River Basin mainly focuses on rainfall and flood control, a few reports on the change of water quality in Qujiang River Basin. Hence, this study evaluates the water quality status of Qujiang River Basin through single factor index and CPI, and analyzes the spatiotemporal characteristics of water quality and its pollution sources combined with multivariate statistical technology (MST), aiming to provide data reference and theoretical support for the ecosystem management and water environment protection of Qujiang River Basin.
Materials and methods
Monitoring area
Qujiang River (Fig. 1), is the largest tributary on the left bank of the Jialing River (106°33′-107°16′E, 30°04′-31°03′N). It originates from Tiechuan Mountain in the Micang Mountain at the junction of Sichuan and Shaanxi. Furthermore, the confluence between Sanhui Town and Bahe, is known as Qujiang. It is 723 km long, with a drainage area of 39,211 km2, thus accounting for approximately 26% of the Jialing River drainage area. Qujiang River Basin mainly flows through northeast in Sichuan Province. It is not only a grain production area, but also an area rich in forest and timber resources. In addition, the average annual discharge of Qujiang River Basin is 730 m3/s.
Sampling and chemical analysis
Twelve parameters were selected on the basis of the sampling continuity of all selected monitoring sections (Tuanbaoling, Baita, and Sailong) monthly from 2015 to 2019 in Qujiang River. The samples were analyzed for 12 parameters, which include water temperature (WT), pH, dissolved oxygen (DO), permanganate index (CODMn), five-days biochemical oxygen demand (BOD5), ammonia nitrogen (NH3–N), chemical oxygen demand (COD), total phosphorus (TP), total nitrogen (TN), fluoride (F), fecal coliforms (F.coli), electrical conductivity (EC), and flow rate (Q). All the parameters of water quality were expressed in mg·L−1 except for WT (℃), pH, F.coli (N/L), EC (ms/m), and Q (m3/S). Table 1 shows the water parameters, their units and the methods of analysis.
Data treatment and analysis
The reliability of CA is realized by standardizing the data because of the water parameters differ in quantity and unit of measurement (Alberto et al. 2001; Singh et al. 2005). IBM SPSS 23.0 was used for statistical calculations of all data in this study, including multivariate analysis of the data set on the water quality of the river was conducting using CA, PCA, and DA (Simeonov et al. 2003). In addition, single factor index method and CPI are used to evaluate the main pollutants and pollution degree of water body in Qujiang River.
Data treatment and analytical methods
Cluster analysis
CA is a group of statistical analysis techniques that divide the research objects into relatively homogeneous groups. According to the similarity between the research variables, the variables with the highest similarity are clustered into a class. The similarity of variables in the same category is high, and there are great differences among variables in different categories (Vega et al. 1998). In this study, the Euclidean square distance method and Ward minimum variance method are used to cluster the water quality parameters of Qujiang River, so as to obtain the time characteristics of water quality in Qujiang River.
Discriminant analysis
DA is a statistical method to classify observation objects, which is used to distinguish clustering results and identify significant pollution indicators (Chen et al. 2017). It is different from cluster analysis. The observation objects are divided into several categories before DA to establish a discriminant function (DF) from existing observation objects of known categories (Wunderlin et al. 2001). The procedure is to determine the discrimination coefficient through a large amount of data of the research object, calculate the discrimination index, and judge what kind a sample belongs to. Compared with DA, CA firstly classifies the samples. Then, it uses DF to distinguish the attributes of the samples and identifies the important pollution parameters of the research objects. The corresponding discriminant function expression is (Johnson and Wichern 1992):
where i is the number of group types (G); n represents the number of indicators participating in discriminant analysis; wij represents the corresponding discrimination coefficient; pij is the number of indicators participating in discriminant analysis; f is the DF; and kj is the intrinsic constant to each group.
Factor analysis/principal component analysis
The principal component analysis (PCA), also known as quantitative analysis, is a multivariate statistical analysis method that uses the idea of dimension reduction to recombine multiple indicators with certain correlation into a few independent comprehensive indicators through certain mathematical methods. It can extract the eigenvalues and eigenvectors from the covariance matrix of original variables. The principal components (PCs) are the uncorrelated (orthogonal) variables obtained by multiplying the original correlated variables with the eigenvector, which is a list of coefficients (loadings or weightings) (Vega et al. 1998; Helena et al. 2000). Factor analysis (FA) is a statistical technique to extract common factors from variable groups, which can further reduce the contribution of less significant variables obtained from PCA. The new group of variables is extracted by rotating the axis defined by PCA, named vari-factors (VFs) (Helena et al. 2000; Vega et al. 1998).
Single factor evaluation and comprehensive pollution index
The single factor evaluation method compares the measured concentration of a pollution index with the evaluation standard of the pollution index, and uses the category of the single index with the worst water quality to determine the comprehensive water quality category of the water body. The comprehensive pollution index method is a water quality evaluation method that adds the single factor index to calculate their arithmetic mean. This method can not only judge the water pollution status of rivers, but also analyze the change trend of water quality. Table 2 shows the comprehensive pollution index and its corresponding water pollution degree.
where Pi is the pollution index of water quality parameter i; Ci is the measured concentration of water quality parameter i; Si is the class 3 standard limit of water quality parameter i in the environmental quality standard for surface water (GB3838-2002); P is the comprehensive pollution index; n is the total number of indicators.
Result
Classification of water quality parameters of Qujiang River
Combined with the environmental functions and protection objectives of surface water, the water quality of Qujiang River is judged by whether it meets the class 3 value of Environmental quality standards for surface water (GB3838-2002, China). Figure 2 shows that the water quality parameters of Qujiang River basically meet the class 3 value (GB3838-2002, China). Among them, TN concentration (Fig. 2h) in Qujiang River exceeds class 3 value of environmental quality standards for surface water for most of the time, and even exceeds class 5 value. Therefore, the high content of nitrogen nutrients is the key index of Qujiang River water quality control. The number of F.coli in class 3 surface water should be less than 10,000, while the number of F.coli (Fig. 2j) in Qujiang River is much higher than that in surface water for some time. In January 2015, the maximum number of F.coli reached 92,000 in Tuanbaoling Section, it is 9.2 times of Class 3 value (GB3838-2002, China).
Main pollutants and pollution degree of water quality in Qujiang River
Table 3 shows the value of the single factor index and comprehensive pollution index of water quality parameters at the three monitoring sections (Tuanbaoling, Baita, and Sailong) from 2015 to 2019. The CPI of the three monitoring sections varies from 0.62 to 1.06 and the water quality is characterized by slight pollution. However, the CPI of Tuanbaoling Section more than 1, and the water quality shows heavy pollution. In addition, the single factor index of TN in three monitoring sections and F.coli in Tuanbaoling is more than 1, respectively, indicating that the TN and F.coli in this section exceed the specified water quality standard limit, and the single factor index of TN is large, which further indicates that the more the water quality exceeds the standard, the more serious it is.
Time grouping of water quality parameters of Qujiang River
Through clustering, the pedigree map is divided into the following three groups when the squared Euclidean distance is ≥ 20 and < 25 according to the similarity characteristics of water quality (Fig. 3): Group 1 corresponded to dry season, including January-April and November–December; Group 2 with the lone month of July, was consistent with the flood season; and Group 3 (May–June and August–October) covers the flat season. The value of Wilks’ lambda for the DF is small (0.000), the χ2 value is high 38.81, and the significance (0.003) is less than 0.05 (Table 4), indicating that the time DA is significant. Tables 5 and 6 present the DFs and classification matrices (CMs), respectively, as obtained by using the temporal DA. These tables show that stepwise DA requires only four main indicators of water quality to construct the DFs. At the same time, pH, CODMn, BOD5, and TP are the most important water quality parameters to distinguish the temporal groups. Figures 3, 4, 5, 6, 7 show the results of the temporal DA of water quality parameters in Qujiang River.
Spatial distribution characteristics of water quality in Qujiang River
Independent sample t-test was used to compare the spatial differences of water quality among monitoring sections. The results show significant differences among the pH, CODMn, NH3–N, TN, F.coli, and Q in the three monitoring sections during a five-years period (2015–2019) (Table 7).
The pH level is weakly alkaline and varied slightly in Tuanbaoling, Baita, and Sailong, ranging from7.11 to 8.74 mg/L, 7.50 to 8.64 mg/L, and 7.29 to 8.45 mg/L, respectively. The CODMn contents range from 1.20 to 5.10 mg/L, 2.04 to 5.50 mg/L, and 1.88 to 4.30 mg/L, respectively. All the values meet class 3 value of environmental quality standards for surface water (GB3838-2002, China). The corresponding NH3-N contents ranged from 0.06 to 0.68 mg/L, 0.12 to 0.74 mg/L, and 0.11 to 0.38 mg/L, respectively. The TN values at Tuanbaoling, Baita, and Sailong varied in the range of 1.11 to 2.88 mg/L, 0.79 to 3.20 mg/L, and 0.83 to 2.68 mg/L, respectively. In addition, significant differences were observed between Tuanbaoling and Baita and between Tuanbaoling and Sailong. The TN content exceed class 5 value of environmental quality standards for surface water. The F.coli values in Tuanbaoling, Sailong, and Baita ranged from 1115 to 92,000 N/L, 1700 to 24,000, and 490 to 24,000 N/L, respectively. Significant differences in F.coli and Q are found between Tuanbaoling and Baita and between Tuanbaoling and Sailong. In particular, the Q level at Tuanbaoling, Baita, and Sailong ranged from 58.80 to 1968.12 m3/s, 46.4 to 3750 m3/s, and 38.70 to 2530 m3/s, respectively.
Identification of source affecting water quality variations
The PC loadings are classified as strong, moderate, and weak, which correspond to absolute loading values of > 0.75, 0.75–0.50, and 0.50–0.30, respectively. The KMO is 0.642 and the significance level is 0 in this study, indicating significant relationships among variables and suitability for PCA. The result shows that the PCA of the three data sets four PCs for the dry season and flood season and five PCs for the flat season with eigenvalues > 1, thus explaining 58.23, 82.94, and 73.23% of the total variance, respectively (Table 8).
Discussion
Water quality evaluation of Qujiang River
TN and F.coli are water quality parameters with serious pollution in Qujiang River, especially TN (Fig. 2, Table 3). We found that the content of nitrogen nutrients of each sampling point in Qujiang River is high and exceed the class V value water standard of surface water for a long time, which shows that the content of nitrogen nutrients is not only affected by the time change caused by nature, but also affected by the discharge of long-term man-made activities (Barakat et al. 2016), especially the discharge of domestic sewage and industrial wastewater from agricultural production (livestock and poultry breeding) for a long time (Wang et al. 2015). In addition, previous studies have confirmed that atmospheric nitrogen deposition cannot be ignored and has become an important source of nitrogen load in water bodies. Atmospheric nitrogen deposition is also an important reason for the increase of nitrogen nutrient content in rivers (Liu et al. 2014). The number of F.coli in Tuanbaoling in 2019 exceeds class 3 value (GB3838-2002, China), which is affected by the discharge of local agricultural wastewater, especially the sewage generated by livestock and poultry breeding (Zhang et al. 2012). Therefore, the water quality of Qujiang river basically meet class 3 value, but the management of external nitrogen nutrient input should be strengthened.
Temporal characteristics of water quality in Qujiang River
The water quality is affected not only by human activities but also related to hydrological changes, such as rainfall difference between dry season and flood season (Xiang et al. 2020; Dong et al. 2010). In this study, the water quality shows evident time-related change. The average pH of the Group1 (7.91) is relatively higher than those of the Group 2 (7.76) and Group 3 (7.82) because there are still a few factories along Qujiang River directly discharge alkaline industrial wastewater into the river without effective treatment. In addition, the Group 1 contains the dry season, during which the precipitation is less, leading weakened self-purification effect of the river and the dilution capacity of pollutants is reduced (Wu et al. 2017; Gurjar et al. 2019). CODMn concentration is closely related to local economic development, sewage discharge and livestock and poultry breeding. Furthermore, it is an important index that reflect the degree of organic pollution in Qujiang River (Ding et al. 2019; Lee et al. 2016). In the study, the CODMn level of the Group 1 (2.66 mg/L) and the Group 3 (3.13 mg/L) are lower than that of the Group 2 (3.40 mg/L). The phenomenon is due to the large urban population density and the discharge of domestic sewage and industrial wastewater, which increases the organic pollution of Qujiang water body. In addition, the second group is in rainy season and the rainfall is abundant and the surface runoff is large in flood season. The organic pollutants generated by human activities enter the river with the surface runoff, increasing the organic matter concentration of the river water body (Razmkhah et al. 2009; Ji and Wang, 2019). BOD5 refers to the amount of DO consume by microorganisms to decompose certain oxidizable substances, especially organic, in a certain volume of water within five days (Dan et al. 2017). It is a comprehensive index that can reflect the content of organic pollutants in the water body. The average of BOD5 of the Group 2 (2.51 mg/L) are higher than those of the Group 1 (2.27 mg/L) and Group3 (2.31 mg/L) in this study, but the average value of the three groups is within the class 3 value of environmental quality standards for surface water (GB3838-2002, China). Meanwhile, nutrients are the necessary trace elements for the growth of aquatic organisms and the main driving force of water eutrophication (Beusen et al. 2015). The TP level is higher in the Group 2 (0.16 mg/L) than Group 1 (0.09 mg/L) and Group 3 (0.10 mg/L). The Group 2 is in summer, with high temperature and strong photosynthesis of algae. In this season, the increase of temperature enhanced the activity of microorganism. It also promoted the consumption of DO in the interstitial water of the sediment. Moreover, it facilitates the release of Fe/Al-p, which is conducive to the release of phosphorus from the sediment to the overlying water (Li et al. 2007; Holmroos et al. 2009; Cheng et al. 2020). In summary, water quality parameters are interrelated, such as WT and DO (Alizadeh et al. 2018).
The water quality of Qujiang River basically meet class 3 value of environmental quality standards for surface water except TN and F.coli, and the water quality in the flood season (Group 2) is worse than that in the dry season (Group 1) and the flat season (Group 3). Therefore, the department in charge of environmental protection management should strengthen the regulation and control of man-made pollutant emissions in the flood season. It should also appropriately increase the frequency of water quality monitoring in this period to reduce the impact of climate change on water quality measurement.
Causes of spatial distribution of water quality in Qujiang River
The six parameters, including pH, CODMn, NH3-N, TN, F.coli, and Q, exhibited significant differences (P < 0.05). The pH value of water is a comprehensive reflection of water chemical characteristics, and it is one of the important indexes to evaluate the water quality (Temporetti et al. 2019). It can directly reflect the amount of carbon dioxide (CO2), organic acids and water pollution status (Li 2005). Compared with Tuanbaoling (7.82) and Sailong (7.86), the average of pH (7.89) in Baita is slightly higher. In addition, significant differences were observed between Tuanbaoling and Baita, and between Tuanbaoling and Sailong. The reason for this phenomenon is that Baita is located in the Economic Development Zone of Guangan City, with many factories and large amount of industrial wastewater discharge, which is greatly affected by human activities. At the same time, most of the lands use for urban construction, and the buffer ability of land is weak (Kirschner et al. 2017; Sliva and Williams 2001). The alkaline wastewater flows into the river with the surface runoff, which increase the pH value of the water body in Baita. Moreover, the Sailong section is located at the lower reaches of the Baita. Due to the continuity and fluidity of the river, the pH values of the water bodies in the Baita section and the Sailong section are similar to each other, and they are significantly higher than that in Tuanbaoling (Dan et al. 2019). The concentration of CODMn can reflect the severity of organic pollution, and it is an important index for water environment quality evaluation and pollution control assessment (Wang et al. 2022). The average concentration of CODMn at Baita (3.16 mg/L) was higher than Tuanbaoling (2.01 mg/L) and Sailong (2.81 mg/L). Meanwhile, Baita has a significant difference from Sailong and Tuanbaoling. This phenomenon is due to Baita section has dense population, developed industry and commerce, and high content of exogenous organic pollutants (Kumar et al. 2017). The proportion of forest land and grassland area in Baita section is low, the microbial diversity in soil is low, and the degradation ability of microorganisms to organic pollutants is weak, which makes more organic matter enter the river, resulting in higher CODMn content in Qujiang River Basin (Sliva and Williams 2001; Tang et al. 2018). In addition, some studies have reported that DO and nutrients have some effects on CODMn (Xiang et al. 2021; Liu et al. 2021). Compared with Baita, there is more agricultural land in Tuanbaoling and Sailong Sections, and the self-purification capacity of water body is relatively strong, and the permanganate index decreases (Jiao et al. 2019). NH3–N was relatively stable but varied slightly at the three monitoring sections. Moreover, significant differences in its levels existed between Tuanbaoling and Baita, as well as between Tuanbaoling and Sailong. The sources of NH3–N pollution were complex, which were mainly pollution from people’s daily activities and pollution from agricultural livestock (Zhang et al. 2018; Liu et al. 2020). The TN level is higher in Tuanbaoling than Baita and Sailong because Tuanbaoling is located in rural areas, and the surrounding area is mostly agricultural land. Hence, the unabsorbed nitrogen fertilizer flows into the river with the surface runoff, which increased the TN content of the river (Ji et al. 2007; Zhang et al. 2019). The F.coli level is significantly higher in Tuanbaoling (12,947.00 N/L) than Baita (7428.33 N/L) and Sailong (5076.33 N/L), thus exceeding the class III value environmental quality standards for surface water. These results suggest that human and animal activities had a negative effect on water quality. Compared with Tuanbaoling and Sailong, the pollution in Baita section is generally more serious. Thus, the supervision and management in Baita should be strengthen. Moreover, the responsible body for the supervision of the section must optimize the regional land type reasonably, and improve the quality of water environment (Zhang and Jiang 2020; Wang et al. 2020a, b).
Identification of pollution sources of Qujiang River
In dry season, four PCs are obtained with eigenvalues more than 1 (Kaiser Normalization), which explain approximately 58.23% of the total variance for the dataset (Table 8). The first factor (PC1), which accounts for 18.73% of the total variance, has moderate positive loadings of DO, NH3-N, TN, and EC, moderate negative loading of WT. This component is in line with the nutrient content and it can be attributed to spring ploughing occurred, in which a large amount of nitrogen fertilizer would be applied in the soil, and the residual nitrogen fertilizer flows into the river with the surface runoff in this season (Guan et al. 2020; Zhang et al. 2019; Shrestha and Kazama 2007). The EC reflects the salinity in the river, and the river conductivity is high in most periods. TN and NH3-N are important factors affecting the growth of algae in river water, and NH3-N is also the toxicity index and oxygen consumption index of river water, and the change of water temperature is inversely proportional to DO (Kumar et al. 2022; Bharathi et al. 2022). PC2, which explains 16.05% of the variance, shows moderate negative loading on F.coli, moderate positive loading on CODMn. In addition, PC2 has strong positive loading on pH. This is due to non-point source pollution caused by human activities, especially the discharge of industrial and agricultural wastewater (Zeinalzadeh and Rezaei 2017). PC3 explains 13.13% of the total variance. It has a moderate positive loading on BOD5, TP, and F. Organic pollution and nutrient variables may be affected by industrial domestic source emissions (Varol et al. 2020). PC4, which accounts for 10.32% of the total variance, has a moderate positive loading on Q. PC1, PC3, and PC4 represent nutrition component and organic pollution, which is indicative of the mixed source of contamination comprising of natural processes as well as anthropogenic inputs, including the discharge of domestic sewage and industrial wastewater, especially phosphorous wastewater, which might increase the risk of eutrophication (Qian et al. 2021; Zhang et al. 2017).
In the flood season, among the total four significant PCs, PC1 accounts for 39.82% of the total variance, has strong positive loading on TP, TN, and F (loading > 0.75), moderate positive loading on BOD5, NH3-N and Q. In addition, it has strong negative loading on WT. It can reflect the degree of eutrophication and organic pollution of the river, thus suggesting that the anthropogenic pollution from the industrial pollution and agricultural pollution (Zhao et al. 2012). At the same time, higher temperature promotes microbial activity in the water in this period. They mineralized the organic nitrogen and phosphorus in the sediment and transformed them into dissolved inorganic nitrogen and phosphorus into the overlying water (Jiang et al. 2008; Jin et al. 2005). PC2 explains the 18.37% of the total variance. It has strong positive loading on DO, strong negative loading on pH, and moderate negative loadings on F.coli. This phenomenon is mainly due to the point source pollution caused by the industrial and agricultural wastewater discharged (Wang et al. 2012; Qian et al. 2021). PC3, explaining 15.85% of the total variance, contains strong positive loading on EC, moderate negative loading on CODMn. PC4 explains 8.90% of the total variance, which was the lowest variance. PC3 and PC4 show that natural processes and anthropogenic input caused mixed pollution to the water environment.
In the flat season, five PCs explain 73.23% of the total variances (Table 8). PC1, accounting for 23.87% of the total variance, shows strong positive loading on TP, moderate positive loadings on NH3-N and Q, and moderate negative loading on WT. PC2 explains 18.33% of the total variance, including moderate positive loading on BOD5, F, and EC, moderate negative loading on CODMn. PC1 and PC2 represent organic pollution in this period, which were affected mainly by the discharge of the pollution from people’s daily activities and agricultural livestock (Zhang et al. 2017; Liu et al. 2020). PC3 (12.45% of total variance) has moderate positive loading on pH, DO and F.coli. Meanwhile, PC4 account for 9.72% of the total variance, has a moderate positive loading on pH. PC3 and PC4 mainly represent the industrial pollution along the Qujiang River Basin. PC5, accounting for 8.86% of the total variance, shows positive loading on WT. Therefore, the results imply that the main problem in the Qujiang River is the high water organic and nitrogen nutrient pollutant content.
Conclusion
The results show that the water quality of Qujiang River basically meet the class 3 value of environmental quality standards for surface water (GB3838-2002, China). CPI varies from 0.62 to 1.06 and the water quality is characterized by slight pollution at the three monitoring sections. The months can be divided into three groups on the basis of similarities of the water quality characteristics: Group 1 (dry season), which includes January-April and November–December; Group 2 (flood season), that is, July; Group 3 (flat season), which consists of May–June and August–October. PCA identified four principal components (PCs) for the dry season and flood season, and five PCs for the flat season, thus explaining 58.23, 82.94, and 73.23% of the total variance, respectively. Moreover, the pollution is more serious in Baita than Tuanbaoling and Sailong section and the results suggest that the main pollution in the Qujiang River is the high water organic and nitrogen nutrient content. Hence, monitoring and protection need to be strengthened in the Baita section of Qujiang River. Nevertheless, the Qujiang River selected for this study belongs to the Jialing River system, which mainly flows through Sichuan Province. Most of the basins in the basin are basins, so the study is not universal and there are certain limitations on the topography in the basin. Therefore, in the future research, more types of rivers should be covered as much as possible, and the spatial and temporal variation characteristics of water quality in different regions should be compared and analyzed, so as to provide important reference for the management and protection of water resources in China and even the world.
Data Availability
All data generated or analyzed during this study are included in this published article.
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Funding
This study was funded by the National Natural Science Foundation of China [Grant Nos. 41807458], Nanchong science and technology planning projects [Grant Nos. 19YFZJ0076] and the Second Tibetan Plateau Scientific Expedition and Research Program (2019QZKK0501).
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Yang, Y., Huang, X., Wu, Xq. et al. The spatiotemporal variations characteristic and pollution evaluation of water quality in Qujiang River, China. Appl Water Sci 13, 32 (2023). https://doi.org/10.1007/s13201-022-01829-7
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DOI: https://doi.org/10.1007/s13201-022-01829-7