Application of a Hydrodynamic and Water Quality Model for Inland Surface Water Systems

Liu, Lubo

doi:10.5772/intechopen.74914

Cited by 8 publications

(14 citation statements)

References 23 publications

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“…The data required for these models are commonly large. Complex models consider the estimation of runoff, soil erosion, sediment and pollutant loading based on theoretical consideration of mass, momentum, and energy [ 94 ]. Complex models can not only address a wide range of watershed-scale hydrology and water quality issues, that include short- and long-term simulations of runoff, sediment, and pollutant loads, but also supply different algorithm options for various physical processes to more accurately describe the processes mathematically.…”

Section: Watershed-scale Nonpoint Source Pollution Model Evaluationmentioning

confidence: 99%

Review of Watershed-Scale Water Quality and Nonpoint Source Pollution Models

2020

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Watershed-scale nonpoint source (NPS) pollution models have become important tools to understand, evaluate, and predict the negative impacts of NPS pollution on water quality. Today, there are many NPS models available for users. However, different types of models possess different form and structure as well as complexity of computation. It is difficult for users to select an appropriate model for a specific application without a clear understanding of the limitations or strengths for each model or tool. This review evaluates 14 more commonly used watershed-scale NPS pollution models to explain how and when the application of these different models are appropriate for a given effort. The models that are assessed have a wide range of capacities that include simple models used as rapid screening tools (e.g., Long-Term Hydrologic Impact Assessment (L-THIA) and Nonpoint Source Pollution and Erosion Comparison Tool (N-SPECT/OpenNSPECT)), medium-complexity models that require detail data input and limited calibration (e.g., Generalized Watershed Loading Function (GWLF), Loading Simulation Program C (LSPC), Source Loading and Management Model (SLAMM), and Watershed Analysis Risk Management Frame (WARMF)), complex models that provide sophisticated simulation for NPS pollution processes with intensive data and rigorous calibration (e.g., Agricultural Nonpoint Source pollution model (AGNPS/AnnAGNPS), Soil and Water Assessment Tool (SWAT), Stormwater Management Model (SWMM), and Hydrologic Simulation Program Fortran (HSPF)), and modeling systems that integrate various sub-models and tools, and contain the highest complexity to solve all phases of hydrologic, hydraulic, and chemical dynamic processes (e.g., Automated Geospatial Watershed Assessment Tool (AGWA), Better Assessment Science Integrating Point and Nonpoint Sources (BASINS) and Watershed Modeling System (WMS)). This assessment includes model intended use, components or capabilities, suitable land-use type, input parameter type, spatial and temporal scale, simulated pollutants, strengths and limitations, and software availability. Understanding the strengths and weaknesses of each watershed-scale NPS model will lead to better model selection for suitability and help to avoid misinterpretation or misapplication in practice. The article further explains the crucial criteria for model selection, including spatial and temporal considerations, calibration and validation, uncertainty analysis, and future research direction of NPS pollution models. The goal of this work is to provide accurate and concise insight for watershed managers and planners to select the best-suited model to reduce the harm of NPS pollution to watershed ecosystems.

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Section: Watershed-scale Nonpoint Source Pollution Model Evaluationmentioning

confidence: 99%

Review of Watershed-Scale Water Quality and Nonpoint Source Pollution Models

2020

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“…Investigative water quality models are both mathematical expressions and expert scientific judgment, which comprise process-based (mechanistic) and data-based (statistical) models. They are effective resources for assessing and predicting pollutant transport (Q. G. Wang et al, 2009;Bai et al, 2011,;Huang et al, 2012), identifying pollution, fate, and behavior of pollutants (Q. G. Wang et al, 2009), simulating and forecasting complex processes in water ecosystems (Liu, 2018), recognizing the spatial and temporal distribution of pollutants in the water, and intensifying decisions regarding how water quality will be altered (Q. Wang et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…The quality of water has been evaluated and modeled with its physical, chemical, and biological characteristics. The relations between the processes related to these characteristics are necessarily multifaceted, and water system managers must pursue to develop a worthy understanding of the main factors and processes that affect the water quality of each local water resource they are responsible for if they are to make correct or improved management decisions (Liu, 2018). The concentrations and distribution of contaminants are influenced by the inactivation of contaminants and some dynamic processes, including diffusion, dispersion, and advection.…”

Section: Introductionmentioning

confidence: 99%

“…The concentrations and distribution of contaminants are influenced by the inactivation of contaminants and some dynamic processes, including diffusion, dispersion, and advection. These processes are closely related to the water flow characteristics, influent and effluent entering and leaving, respectively, the waterbody, wind stress, and temperature stratification (Liu, 2018). Hence, for a better understanding of how the environment and water systems are polluted and to make fruitful decisions and directions, concrete knowledge derived from water quality modeling is significant.…”

Section: Introductionmentioning

confidence: 99%

“…Thus, mathematical water quality modeling coupled with observations for verification and calibration is essential in such cases. Integrated models such as hydrodynamic and water quality models have been extensively developed and used (Liu, 2018) for assessing lakes, rivers, reservoirs, ponds, estuaries, and coastal water in many aspects.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Overview of water quality modeling

Ejigu

2021

Cogent Engineering

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Due to population growth, urbanization, and industrialization, water demands have increased, and the quality of water is degraded. Water quality modeling is a significant tool that aids managers and policymakers in multiscale integrated water resources and environmental management. However, water quality modeling is challenging due to several constraints. The modern application of modeling is essentially utilized by the need to comply with rules and regulations. In view of this, water quality modeling requires the standardization of models, identification of common features of models, the hotspots of pollution, and the current state of policy-relevant models. This review presents an overview of water quality modeling and major models frequently applied for water quality assessment at the catchment and at waterbody scales. This review is intended to highlight the applicability of certain water quality models, and the state of water quality modeling, model classification, and uncertainties. Water quality models are described and selected based on their applicability, strengths, weaknesses, and intended use. Some models are applicable for the specific waterbodies, simulate selected water quality parameters, have uncertainties, are not commercially available, require skilled model users, and have huge data requirements. When selecting suitable models, it is recommended to consider the availability of data, model complexity, and type of waterbody, and intended objectives to be modeled.

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The Hydrodynamic Model using HEC-RAS: The case of Tigris River Downstream of Samarra Barrage (Iraq)

Sabeeh

Alabdraba

2022

IOP Conf. Ser.: Earth Environ. Sci.

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Tigris River is one of the Iraq’s two main rivers. In the present study, one dimensional hydrodynamic model (HEC-RAS) was used to simulate the flow pattern of Tigris River to understand the flow movement. The hydrodynamic model was calibrated by evaluating its performance using Manning’s roughness coefficients which has a final calibration range of 0.018–0.020, with an average of 0.019 in most parts of the study area. The values of the Nash-Sutcliffe coefficient (NSE) and the coefficient of discrimination (R2) were close to 1 which means a high degree of conformity between the simulated and observed data. The validation results show that there is a very close relationship between the observed flow discharge with the hydrodynamic model built by HEC-RAS. This finding would be a very productive tool to estimate the amount of discharge at ungagged locations along the Tigris River downstream of Samarra Barrage.

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Application of a Hydrodynamic and Water Quality Model for Inland Surface Water Systems

Cited by 8 publications

References 23 publications

Review of Watershed-Scale Water Quality and Nonpoint Source Pollution Models

Review of Watershed-Scale Water Quality and Nonpoint Source Pollution Models

Overview of water quality modeling

The Hydrodynamic Model using HEC-RAS: The case of Tigris River Downstream of Samarra Barrage (Iraq)

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