Abstract

The prediction of algal chlorophyll-a and water clarity in lentic ecosystems is a hot issue due to rapid deteriorations of drinking water quality and eutrophication processes. Our key objectives of the study were to predict long-term algal chlorophyll-a and transparency (water clarity), measured as Secchi depth, in spatially heterogeneous and temporally dynamic reservoirs largely influenced by the Asian monsoon during 2000–2017 and then determine the reservoir trophic state using a multiple linear regression (MLR), support vector machine (SVM) and artificial neural network (ANN). We tested the models to analyze the spatial patterns of the riverine zone (Rz), transitional zone (Tz) and lacustrine zone (Lz) and temporal variations of premonsoon, monsoon and postmonsoon. Monthly physicochemical parameters and precipitation data (2000–2017) were used to build up the models of MLR, SVM and ANN and then were confirmed by cross-validation processes. The model of SVM showed better predictive performance than the models of MLR and ANN, in both before validation and after validation. Values of root mean square error (RMSE) and mean absolute error (MAE) were lower in the SVM model, compared to the models of MLR and ANN, indicating that the SVM model has better performance than the MLR and ANN models. The coefficient of determination was higher in the SVM model, compared to the MLR and ANN models. The mean and maximum total suspended solids (TSS), nutrients (total nitrogen (TN) and total phosphorus (TP)), water temperature (WT), conductivity and algal chlorophyll (CHL-a) were in higher concentrations in the riverine zone compared to transitional and lacustrine zone due to surface run-off from the watershed. During the premonsoon and postmonsoon, the average annual rainfall was 59.50 mm and 54.73 mm whereas it was 236.66 mm during the monsoon period. From 2013 to 2017, the trophic state of the reservoir on the basis of CHL-a and SD was from mesotrophic to oligotrophic. Analysis of the importance of input variables indicated that WT, TP, TSS, TN, NP ratios and the rainfall influenced the chlorophyll-a and transparency directly in the reservoir. These findings of the algal chlorophyll-a predictions and Secchi depth may provide key clues for better management strategy in the reservoir.

Highlights

  • In the 21st century, eutrophication has become one of the major water quality issues in dam reservoirs due to nutrient enrichment worldwide [1]

  • The mean and maximum total suspended solids (TSS), total nitrogen (TN), total phosphorus (TP), water temperature (WT), Cond and CHL-a were in higher concentrations in the riverine zone compared to transitional and lacustrine zone due to surface run-off from the watershed

  • Our study showed that the support vector machine (SVM) indicated the highest prediction accuracy for chlorophyll-a and transparency (Secchi depth) compared to multiple linear regression (MLR) and artificial neural network (ANN) in Riverine Zone (Rz), Lacustrine Zone (Lz) and TZ during premonsoon, monsoon and postmonsoon

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Summary

Introduction

In the 21st century, eutrophication has become one of the major water quality issues in dam reservoirs due to nutrient enrichment worldwide [1]. This phenomenon has direct and indirect negative impacts on the aquatic system and public health including deterioration of aquatic ecosystem health, impedes drinking water availability, hypoxia, fish kills and toxin production [2,3,4]. Secchi depth is considered a second major feature affecting the internal nutrient release and turbidity due to sediment and surface runoff related issues in reservoirs [14]. In the aquatic ecosystem especially in a freshwater system, Secchi depth has been decreasing due to eutrophication, sediment, top surface soil run-off and human activities [15,16]

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