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Autori principali: Jie Wang, Shiguang Miao, Ashok Kumar Pokharel, Jingjing Dou, Bin Ma, Chunlei Meng, Yuhuan Li
Natura: Artículo Open Access
Pubblicazione: Wiley 2024
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Accesso online:https://onlinelibrary.wiley.com/doi/10.1002/hyp.70021
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author Jie Wang
Shiguang Miao
Ashok Kumar Pokharel
Jingjing Dou
Bin Ma
Chunlei Meng
Yuhuan Li
author_facet Jie Wang
Shiguang Miao
Ashok Kumar Pokharel
Jingjing Dou
Bin Ma
Chunlei Meng
Yuhuan Li
Jie Wang
Shiguang Miao
Ashok Kumar Pokharel
Jingjing Dou
Bin Ma
Chunlei Meng
Yuhuan Li
collection Wiley Open Access
contents Developing a Lateral Terrestrial Water Flow Scheme to Improve the Representation of Land Surface Hydrological Processes in the Noah‐MP of WRF‐Hydro Jie Wang Shiguang Miao Ashok Kumar Pokharel Jingjing Dou Bin Ma Chunlei Meng Yuhuan Li Hydrological Processes ABSTRACTLateral terrestrial water flow in the Weather Research and Forecasting (WRF) Model and its hydrologically enhanced version, WRF‐Hydro, is calculated on a routing grid based on infiltration excess in Land Surface Model (LSM) grid disaggregates to the routing grids. However, this design neglects the lateral terrestrial water flow within LSM grids and does not resolve water lateral transport in LSM. In this study, we develop a lateral terrestrial water flow scheme in the Noah with multiparameterization (Noah‐MP) of WRF‐Hydro grids to address this knowledge gap and evaluate its influence on land surface hydrological processes. Our results indicate that lateral terrestrial water flow leads to 62.3% of grid surface water outflow, resulting in a decrease in accumulated water depth by 123.88 mm. In urban areas, the accumulated water depth further reduces by 21.11 mm when considering the pipe discharge scheme. Compared to the default WRF‐Hydro simulation, the lateral terrestrial water flow combined with pipe discharge can effectively advance the calibrated WRF‐Hydro modelling capability and reproduce the water depth reasonably compared to the observation in urban areas. Further, our analysis indicates that the decreasing lateral terrestrial water flow in LSM primarily reduces overland flow and increases streamflow in routing grids, mainly through redistributing water from the steep slopes towards the lower elevations and ultimately converting it to streamflow in the channel network. 10.1002/hyp.70021 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1002/hyp.70021
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spellingShingle Developing a Lateral Terrestrial Water Flow Scheme to Improve the Representation of Land Surface Hydrological Processes in the Noah‐MP of WRF‐Hydro
Jie Wang
Shiguang Miao
Ashok Kumar Pokharel
Jingjing Dou
Bin Ma
Chunlei Meng
Yuhuan Li
Hydrological Processes
Developing a Lateral Terrestrial Water Flow Scheme to Improve the Representation of Land Surface Hydrological Processes in the Noah‐MP of WRF‐Hydro Jie Wang Shiguang Miao Ashok Kumar Pokharel Jingjing Dou Bin Ma Chunlei Meng Yuhuan Li Hydrological Processes ABSTRACTLateral terrestrial water flow in the Weather Research and Forecasting (WRF) Model and its hydrologically enhanced version, WRF‐Hydro, is calculated on a routing grid based on infiltration excess in Land Surface Model (LSM) grid disaggregates to the routing grids. However, this design neglects the lateral terrestrial water flow within LSM grids and does not resolve water lateral transport in LSM. In this study, we develop a lateral terrestrial water flow scheme in the Noah with multiparameterization (Noah‐MP) of WRF‐Hydro grids to address this knowledge gap and evaluate its influence on land surface hydrological processes. Our results indicate that lateral terrestrial water flow leads to 62.3% of grid surface water outflow, resulting in a decrease in accumulated water depth by 123.88 mm. In urban areas, the accumulated water depth further reduces by 21.11 mm when considering the pipe discharge scheme. Compared to the default WRF‐Hydro simulation, the lateral terrestrial water flow combined with pipe discharge can effectively advance the calibrated WRF‐Hydro modelling capability and reproduce the water depth reasonably compared to the observation in urban areas. Further, our analysis indicates that the decreasing lateral terrestrial water flow in LSM primarily reduces overland flow and increases streamflow in routing grids, mainly through redistributing water from the steep slopes towards the lower elevations and ultimately converting it to streamflow in the channel network. 10.1002/hyp.70021 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Developing a Lateral Terrestrial Water Flow Scheme to Improve the Representation of Land Surface Hydrological Processes in the Noah‐MP of WRF‐Hydro
topic Hydrological Processes
url https://onlinelibrary.wiley.com/doi/10.1002/hyp.70021