Modeling of streamflow in a 30 km long reach spanning 5 years using OpenFOAM 5.x

Developing accurate and efficient modeling techniques for streamflow at the tens-of-kilometers spatial scale and multi-year temporal scale is critical for evaluating and predicting the impact of climate- and human-induced discharge variations on river hydrodynamics. However, achieving such a goal is...

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Bibliographic Details
Published in:Geoscientific Model Development 2022-04, Vol.15 (7), p.2917-2947
Main Authors: Chen, Yunxiang, Bao, Jie, Fang, Yilin, Perkins, William A, Ren, Huiying, Song, Xuehang, Duan, Zhuoran, Hou, Zhangshuan, He, Xiaoliang, Scheibe, Timothy D
Format: Article
Language:English
Subjects:
Acoustic Doppler Current Profiler
Analysis
Bathymetry
bed shear stress
Boundary conditions
Calibration
CFD
Climate
Climate change
Climate prediction
Coefficients
Computational efficiency
Computational fluid dynamics
Computer applications
Computing costs
Computing time
Correlation coefficient
Correlation coefficients
Creeks & streams
Discharge
Doppler sonar
Dynamic pressure
Efficiency
Evaluation
Flow velocity
Fluid dynamics
Fluid mechanics
GEOSCIENCES
Heterogeneity
Human influences
Hydraulic models
Hydraulic roughness
Hydrodynamics
Hydrology
Hydrostatic pressure
Impact prediction
Inflow
large-scale and long-term modeling
Model accuracy
Modelling
OpenFOAM
Optimization
Outflow
Polls & surveys
River corridor
Rivers
Roughness
Sediment transport
Stream discharge
Stream flow
Streambeds
Streamflow
streamwater
Surveying
Surveys
Three dimensional models
Topography
Turbulence models
Variation
Velocity
Velocity distribution
Water depth
Water quality
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Description
Summary:Developing accurate and efficient modeling techniques for streamflow at the tens-of-kilometers spatial scale and multi-year temporal scale is critical for evaluating and predicting the impact of climate- and human-induced discharge variations on river hydrodynamics. However, achieving such a goal is challenging because of limited surveys of streambed hydraulic roughness, uncertain boundary condition specifications, and high computational costs. We demonstrate that accurate and efficient three-dimensional (3-D) hydrodynamic modeling of natural rivers at 30 km and 5-year scales is feasible using the following three techniques within OpenFOAM, an open-source computational fluid dynamics platform: (1) generating a distributed hydraulic roughness field for the streambed by integrating water-stage observation data, a rough wall theory, and a local roughness optimization and adjustment strategy; (2) prescribing the boundary condition for the inflow and outflow by integrating precomputed results of a one-dimensional (1-D) hydraulic model with the 3-D model; and (3) reducing computational time using multiple parallel runs constrained by 1-D inflow and outflow boundary conditions. Streamflow modeling for a 30 km long reach in the Columbia River (CR) over 58 months can be achieved in less than 6 d using 1.1 million CPU hours. The mean error between the modeled and the observed water stages for our simulated CR reach ranges from −16 to 9 cm (equivalent to approximately ±7 % relative to the average water depth) at seven locations during most of the years between 2011 and 2019. We can reproduce the velocity distribution measured by the acoustic Doppler current profiler (ADCP). The correlation coefficients of the depth-averaged velocity between the model and ADCP measurements are in the range between 0.71 and 0.83 at 75 % of the survey cross sections. With the validated model, we further show that the relative importance of dynamic pressure versus hydrostatic pressure varies with discharge variations and topography heterogeneity. Given the model's high accuracy and computational efficiency, the model framework provides a generic approach to evaluate and predict the impacts of climate- and human-induced discharge variations on river hydrodynamics at tens-of-kilometers and decadal scales.
ISSN:1991-9603
1991-959X
1991-962X
1991-9603
1991-962X
DOI:10.5194/gmd-15-2917-2022