Modeling stream temperature in the <scp>A</scp>nthropocene: An earth system modeling approach

Li, Hong Yi; Leung, L. Ruby; Tesfa, T. K.; Voisin, Nathalie; Hejazi, Mohamad; Liu, Lu; Liu, Ying; Rice, Jennie S.; Wu, Huan; Yang, Xiaofan

doi:10.1002/2015ms000471

Cited by 35 publications

(62 citation statements)

References 34 publications

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“…This study adopts a physically based stream temperature model that is coupled with the Community Land Model (CLM) version 4.0 and a WM model (Li, Ruby Leung, Tesfa, et al, ), as shown in Figure . Individual components of Figure are explained below.…”

Section: Methodsmentioning

confidence: 99%

“…This alters the flow regime and seasonal variability of stream temperature (Yang et al, 2005) through the storage of water during high-flow periods and enhancement of low flows during the summer dry season (WWF, 2006;Ziv et al, 2012). On the contrary, water extraction that withdraws water directly from unregulated local streams reduces local discharge and tends to warm the stream especially in summer (Li, Ruby Leung, Tesfa, et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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River Regulation Alleviates the Impacts of Climate Change on U.S. Thermoelectricity Production

Zhang

Leung

et al. 2020

JGR Atmospheres

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Climate change is projected to elevate stream temperature and poses threats to thermoelectric power generation. Although two thirds of the global rivers are regulated by dams, the impacts of river regulation on stream temperature and thermoelectricity production have not been evaluated in previous studies. Using a state‐of‐the‐art integrated water cycle model and a power generation model, we quantify the impacts of river regulation on stream temperature and usable capacity of once‐through thermoelectric power in the United States. Our study demonstrates that by lowering stream temperature and increasing water availability during the low‐flow season, river regulation can curtail the loss of summer power plant usable capacity induced by climate change. The alleviation of power loss by water management is comparable to that resulting from emission mitigation that reduces warming in the future. Our new findings highlight the necessity of incorporating water management effects in thermoelectric power vulnerability assessment.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

River Regulation Alleviates the Impacts of Climate Change on U.S. Thermoelectricity Production

Zhang

Leung

et al. 2020

JGR Atmospheres

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“…Significant effort and progress have been made in large-scale representation and modeling of water management impact of reservoirs on streamflow (Hanasaki et al, 2008;Voisin et al, 2017Voisin et al, , 2013 and temperature (Li et al, 2015;Miara et al, 2017;Niemeyer et al, 2018;van Beek et al, 2012;van Vliet et al, 2012van Vliet et al, , 2013. In modeling stream temperature in the continental United States, Li et al (2015) suggested the inclusion of reservoir stratification models in river transport models to better represent stream temperature downstream of reservoirs. When it comes to understanding the stratification effect on stream temperature, most studies have focused on a single reservoir (for example, Bonnet et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

A Multilayer Reservoir Thermal Stratification Module for Earth System Models

Yigzaw

Fang

et al. 2019

J Adv Model Earth Syst

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Thermal stratification in reservoirs is a critical process that regulates downstream riverine energy and biogeochemical cycling. Current stratification models either simplify vertical energy process, reservoir geometry or neglecting the effects of reservoir operation. Here we present a new multilayer reservoir stratification model that can be applied for reservoir and stream temperature simulation at regional or global scale. With a multilayer vertical discretization, we introduce a newly developed storage‐area‐depth dataset to improve parameterization of advection processes in and out of the reservoir. The new model better represents vertical temperature gradient and subsequently temperature of water released to downstream. The stratification model is applied to 1,400 reservoirs over the contiguous United States and validated against observed surface, profile, and outflow temperature data over 130 reservoirs subjected to various levels of regulation. The Nash‐Sutcliffe values are higher than 0.5 for about 77% of the validated reservoirs using surface temperature while the average values of root mean square error and bias are 3.6 °C and −1.1 °C, respectively. Using the new reservoir storage‐area‐depth dataset improves the simulation of surface temperature at over 69% of the validated reservoirs compared to using simplified reservoir geometry. The reservoir stratification model contributes to improving predictive understanding of anthropogenic impact on terrestrial hydrological, ecological, and biogeochemical cycles.

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“…Downstream of these reservoirs, the river shows a narrow seasonal range in observed temperature (approximately 4.0 to 10.0 °C), suggesting releases from the cooler hypolimnion of a stratified reservoir. Similarly, Li et al () simulated distributed river temperatures across the continental United States and had the poorest model performance below Hoover Dam which impounds Lake Mead, a stratified reservoir with a long residence time. As a result, Li et al () recommended incorporating thermal stratification into distributed river temperature models.…”

Section: Introductionmentioning

confidence: 99%

A Thermally Stratified Reservoir Module for Large‐Scale Distributed Stream Temperature Models With Application in the Tennessee River Basin

Niemeyer

Cheng

Mao

et al. 2018

Water Resources Research

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River temperatures affect water quality, power plant cooling, and freshwater ecosystems. Stream temperature models that treat river reaches and reservoirs as well‐mixed segments do not capture thermal stratification in reservoirs. To account for the effects of reservoir stratification on downstream water temperatures, we developed a two‐layer stratified reservoir module, which was integrated into the River Basin Model (RBM) to simulate river temperature across a river network with multiple large thermally stratified reservoirs. To evaluate the performance of this model configuration compared to RBM without thermally stratified reservoirs, we simulated river temperature in the Tennessee River Basin in the southeastern United States. We simulated land surface hydrologic fluxes using the Variable Infiltration Capacity (VIC) model and routed runoff using the river routing model RVIC. The two‐layer model configuration reduced the bias in simulated summer river temperature from 6.7 to −1.2 °C downstream of a reservoir with a residence time of 92 days and from 3.0 to −0.7 °C downstream of a reservoir with a residence time of 8 days. Improvement in fall and winter, when reservoirs tend to be well mixed, is minimal. RBM with the two‐layer module also captured the observed longitudinal river temperature variation downstream of a reservoir, with cool temperatures immediately downstream of the reservoir and gradual warming of the river as it flows downstream. Incorporating a simple stratified reservoir module into RBM improves model performance and increases the ability to apply the river temperature model to large basins with multiple large reservoirs.

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Modeling stream temperature in the Anthropocene: An earth system modeling approach

Cited by 35 publications

References 34 publications

River Regulation Alleviates the Impacts of Climate Change on U.S. Thermoelectricity Production

River Regulation Alleviates the Impacts of Climate Change on U.S. Thermoelectricity Production

A Multilayer Reservoir Thermal Stratification Module for Earth System Models

A Thermally Stratified Reservoir Module for Large‐Scale Distributed Stream Temperature Models With Application in the Tennessee River Basin

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