Thermal stratification is an important factor causing deterioration of water quality in source water reservoirs. To explore the occurrence of thermal stratification and its impact on water quality of plain reservoirs in subtropical region, water temperature and main water quality parameters of Reservoir A, B, and C in City S (South China) were continuously monitored from March to July 2021. The results showed that thermal stratification occurred in all the three reservoirs with different stability. Thermal stratification of Reservoir A and C was relatively weak due to shallow water depth (<10 m) and the influence of water diversion, whereas thermal stratification was more stable in Reservoir B with a water depth of approximate 12 m. Thermal stratification hindered transfer of dissolved oxygen (DO) from surface water to the lower water layer, and oxygen consumption by water and sediment in plain reservoirs in subtropical region was relatively high due to high temperature and microbial activity. Therefore, DO concentration dropped rapidly with water depth, leading to anaerobic layers with heights of 2-4 m at the bottom of the three reservoirs. As a result, release of nitrogen, phosphorus, iron and manganese from the sediments was significant, especially in Reservoir B. In early July, the concentrations of total nitrogen, ammonium, total phosphorus, iron and manganese in the bottom layer have all substantially exceeded the standard limits for drinking water source. In general, water quality deterioration caused by thermal stratification of plain reservoirs in subtropical region cannot be ignored, and measures should be taken to combat the hypoxic environment and pollutants release at the bottom layer.

Han B P. Reservoir ecology and limnology in China: a retrospective comment[J]. Journal of Lake Sciences, 2010, 22(2): 151-160.

Lehner B, Liermann C R, Revenga C, et al. High-resolution mapping of the world’s reservoirs and dams for sustainable river-flow management[J]. Frontiers in Ecology & the Environment, 2011, 9(9): 494-502.

Zhang Yunlin, Wu Zhixu, Liu Mingliang, et al. Dissolved oxygen stratification and response to thermal structure and long-term climate change in a large and deep subtropical reservoir (Lake Qiandaohu, China) [J]. Water Research, 2015, 75: 249-258.

Huang Tinglin. Water pollution and water quality control of selected Chinese reservoir basins [M]. Springer, 2015.

Liu Miao, Zhang Yunlin, Shi Kun, et al. Thermal stratification dynamics in a large and deep subtropical reservoir revealed by high-frequency buoy data[J]. Science of the Total Environment, 2019, 651: 614-624.

Conley Daniel J., Paerl Hans W., Howarth Robert W., et al. Controlling Eutrophication: Nitrogen and Phosphorus[J]. Science, 2009, 323(5917): 1014-1015.

Rigosi Anna, Rueda Francisco J. Hydraulic control of short-term successional changes in the phytoplankton assemblage in stratified reservoirs[J]. Ecological Engineering, 2012, 44: 216-226.

Cheng Yifan, Voisin Nathalie, Yearsley John R., et al. Reservoirs Modify River Thermal Regime Sensitivity to Climate Change: A Case Study in the Southeastern United States [J]. Water Resources Research, 2020, 56(6): e2019WR025784.

Zhou Z., Huang T., Li Y., Ma W., Zhou S., Long S. Sediment pollution characteristics and in situ control in a deep drinking water reservoir [J]. J Environ Sci (China), 2017, 52: 223-231.

Lulëzim Shuka, Alqi Çullaj, Spase Shumka, et al. The Spatial and Temporal Variability of Limnological Properties of Bovilla Reservoir (Albania) [J]. Water Resources Management, 2011, 25(12): 3027-3039.

Li Nan, Huang Tinglin, Mao Xuejing, et al. Controlling reduced iron and manganese in a drinking water reservoir by hypolimnetic aeration and artificial destratification[J]. Science of the Total Environment, 2019, 685: 497-507.

Zheng Li-wen, Zhai Wei-dong. Excess nitrogen in the Bohai and Yellow seas, China: Distribution, trends, and source apportionment [J]. Science of the Total Environment, 2021, 794: 148702.

Hu K, Pang Y, Wang H, et al. Simulation study on water quality based on sediment release flume experiment in Lake Taihu, China[J]. Ecological Engineering, 2011, 37(4): 607-615.

Mäkelä K, Tuominen L. Pore water nutrient profiles and dynamics in soft bottoms of the northern Baltic Sea[J]. Hydrobiologia, 2003, 492(1): 43-53.

Perrone U, Facchinelli A, Sacchi E. Phosphorus dynamics in a small eutrophic Italian lake[J]. Water, air, and soil pollution, 2008, 189(1): 335-351.

Schwefel R, Steinsberger T, Bouffard D, et al. Using small‐scale measurements to estimate hypolimnetic oxygen depletion in a deep lake[J]. Limnology and Oceanography, 2018, 63(S1): S54-S67.