Effects of different operational modes on the flood‐induced turbidity current of a canyon‐shaped reservoir: case study on Liuxihe Reservoir, South China

Wang, Sheng; Qian, Xin; Han, Bo; Ling, Luo; Rui, Yong; Wen, Xishan

doi:10.1002/hyp.9534

Cited by 14 publications

(11 citation statements)

References 51 publications

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“…The simulation results from DYRESM-CAEDYM model have been proved to be consistent with the measurements, and could be reproduced well (Wang et al, 2012b(Wang et al, , 2012c. We implemented the model to estimate the dynamics of T, SRP and SS concentration in the scenario with epilimnetic withdrawals (Fig.…”

Section: Model Simulationsupporting

confidence: 60%

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Effect of intensive epilimnetic withdrawal on phytoplankton community in a (sub)tropical deep reservoir

Zhang¹,

Lin²,

Xiao³

et al. 2013

J Limnol

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Withdrawal is an important process in reservoir hydrodynamics, removing phytoplankton with flushed water. Zooplankton，the grazers of phytoplankton, having longer generation times, are even more susceptible than phytoplankton to flushing loss. Therefore phytoplankton are affected not only by abiotic conditions linked to hydrodynamics but also by zooplankton due to weakened grazing pressure. During the Asian Games (November 12-27, 2010 in Guangzhou, China), two intensive epilimnetic withdrawals were conducted in Liuxihe, a deep canyon-shaped reservoir. To examine the influence of the intensive epilimnetic withdrawals on the phytoplankton community, a seven-week field observation and a hydrodynamic simulation were carried out. The observation was divided in two stages: stage 1 represented partial surface vertical mixing period, and stage 2 represented intensive epilimnetic withdrawal period. It was found that phytoplankton abundance and biomass declined with water temperature and partial surface vertical mixing in stage 1. However, the intensive epilimnetic withdrawal reversed this decreasing trend and increased phytoplankton biomass and abundance in stage 2. Phytoplankton showed a higher rate of composition change in stage 2. A numerical model (DYRESM-CAEDYM) simulated scenarios with and without epilimnetic withdrawal to test their effects on abiotic factors (water temperature, suspended sediment and soluble reactive phosphorus) for phytoplankton. The results showed no obvious difference in the abiotic factors between the two scenarios during stage 2. We therefore suggested that the abiotic factors in the water column were probably driven by a seasonal pattern, not by epilimnetic withdrawal. It is likely that the intensive epilimnetic withdrawal could remove large crustaceans. The reduced grazing pressure probably explained the increase of phytoplankton biomass and abundance after the withdrawal. Thus, we suggest that reservoir operation should pay more attention to grazing from large crustaceans. It is recommended that, in the management of reservoirs, intensive epilimnetic withdrawal during autumn should be avoided in order to control excessive phytoplankton in the tropics and subtropics.

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Section: Model Simulationsupporting

confidence: 60%

“…DYRESM-CAEDYM has been calibrated previously in our reservoir, and could be used as a strategic evaluation tool for Liuxihe reservoir management (Wang et al, 2012b;Wang et al, 2012c). So only a brief description will be included as follow.…”

Section: The Model Simulationmentioning

confidence: 99%

Effect of intensive epilimnetic withdrawal on phytoplankton community in a (sub)tropical deep reservoir

Zhang¹,

Lin²,

Xiao³

et al. 2013

J Limnol

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“…This stratification could lead to long periods of anaerobic conditions at the bottom of the reservoir and result in a significant deterioration of water quality as reduced (chemical) species continue to be released from the sediments and enter the hypolimnion (Beutel et al, 2008;Fan and Kao, 2008). Significant turbidity currents following extreme rainfall events have been observed and reported for many reservoirs (Wang et al, 2012b). These high-density inflows coupled with a large amount of suspended matter and dissolved oxygen entering the bottom of the reservoir can immediately increase dissolved oxygen levels and effectively restrain the release of pollutants (Huang et al, 2014a;Liu et al, 2014;Ma et al, 2011).…”

Section: Introductionmentioning

confidence: 97%

Effects of rainfall patterns on water quality in a stratified reservoir subject to eutrophication: Implications for management

Huang

Wei-xing

et al. 2015

Science of The Total Environment

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“…Careful management of reservoir storages, preceding and during large flooding events, can be used 521 to control suspended matter and turbidity levels in the withdrawn water (Wang et al 2013). Similarly, 522 a variety of management options may be considered to better control water quality risks associated 523 with cyanobacterial growth in water supply reservoirs.…”

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confidence: 99%

Extreme weather events: Should drinking water quality management systems adapt to changing risk profiles?

et al. 2015

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Effects of different operational modes on the flood‐induced turbidity current of a canyon‐shaped reservoir: case study on Liuxihe Reservoir, South China

Cited by 14 publications

References 51 publications

Effect of intensive epilimnetic withdrawal on phytoplankton community in a (sub)tropical deep reservoir

Effect of intensive epilimnetic withdrawal on phytoplankton community in a (sub)tropical deep reservoir

Effects of rainfall patterns on water quality in a stratified reservoir subject to eutrophication: Implications for management

Extreme weather events: Should drinking water quality management systems adapt to changing risk profiles?

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