Assessment of Water Quality Using Chemometrics and Multivariate Statistics: A Case Study in Chaobai River Replenished by Reclaimed Water, North China

• Published in: Water (Basel) Vol. 12; no. 9; p. 2551
• Main Authors: Yu, Yilei, Song, Xianfang, Zhang, Yinghua, Zheng, Fandong
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.09.2020
• Subjects: Ammonia; Bicarbonates; Calcite; Calcium ions; Cation exchange; Cation exchanging; Chaobai River; Chemistry; Chemometrics; Chlorophyll; Cluster analysis; Dissolution; Dissolved oxygen; Electrical resistivity; Eutrophication; Groundwater; Gypsum; Isotopes; Isotopic enrichment; Magnesium; Minerals; Multivariate analysis; multivariate statistics; Nitrification; Nitrogen dioxide; Oxidation; Parameters; Phosphorus; Photosynthesis; Phytoplankton; Polyethylene; Potassium; Precipitation; Principal components analysis; Reclaimed water; river water; Rivers; Rocks; Sodium; Stable isotopes; Statistical analysis; Surface water; Temporal variations; Total dissolved solids; Water analysis; Water chemistry; Water quality; Water reuse; Water sampling; Beijing China; China
• ISSN: 2073-4441; 2073-4441
• DOI: 10.3390/w12092551

Dry rivers could be effectively recovered by reclaimed water in North China, while river water quality would be an important issue. Therefore, it is important to understand the spatiotemporal variation and controlling factors of river water. Water samples were collected during March, May, July, September, and November in the year 2010, then 20 parameters were analyzed. The water environment was oxidizing and alkaline, which was beneficial for nitrification. Nitrate was the main nitrogen form. Depleted and enriched isotopes were found in reclaimed water and river water, respectively. Total nitrogen (TN) and total phosphorus (TP) of reclaimed water exceed the threshold of reclaimed water reuse standard and Class V in the surface water quality criteria. Most river water was at the severe eutrophication level. The sodium adsorption ratio indicated a medium harmful level for irrigation purpose. Significant spatial and temporal variation was explored by cluster analysis. Five months and nine stations were both classified into two distinct clusters. It was found that 6 parameters (chloride: Cl−, sulphate: SO42−, potassium: K+, sodium: Na+, magnesium: Mg2+, and total dissolved solids: TDS) had significant upward temporal variation, and 12 parameters (dissolved oxygen: DO, electric conductivity: EC, bicarbonate: HCO3−, K+, Na+, Ca2+, TDS, nitrite-nitrogen: NO2-N, nitrate nitrogen: NO3-N, TN, TP, and chlorophyll a: Chl.a) and 4 parameters (Mg2+, ammonia nitrogen: NH3-N, and the oxygen-18 and hydron-2 stable isotope: δ18O and δ2H) had a significant downward and upward spatial trend, respectively. The Gibbs plot showed that river water chemistry was mainly controlled by a water–rock interaction. The ionic relationship and principal component analysis showed that river water had undergone the dissolution of carbonate, calcite, and silicate minerals, cation exchange, a process of nitrification, photosynthesis of phytoplankton, and stable isotope enrichment. In addition, gypsum and salt rock have a potential dissolution process.