Process Based Calibration of a Continental scale HYPE Model using Soil Moisture and Streamflow Data
Section 1: Publication
Publication Type
Journal Article
Authorship
Bajracharya, A., Ahmed, M. I., Stadnyk, T.A., Asadzadeh, M.
Title
Process Based Calibration of a Continental scale HYPE Model using Soil Moisture and Streamflow Data
Year
2023
Publication Outlet
J. Hydrol. Reg, Studies. 47: 101391.
DOI
ISBN
ISSN
Citation
Bajracharya, A., Ahmed, M. I., Stadnyk, T.A., Asadzadeh, M. (2023) Process Based Calibration of a Continental scale HYPE Model using Soil Moisture and Streamflow Data. J. Hydrol. Reg, Studies. 47: 101391.
https://doi.org/10.1016/j.ejrh.2023.101391
Abstract
Study region
Nelson Churchill River Basin (NCRB), Canada, and USA.
Study Focus
Soil temperature and moisture are essential variables that fluctuate based on soil depth, controlling several sub-surface hydrologic processes. The Hydrological Predictions for the Environment (HYPE) model’s soil profile depth can vary up to four meters, discretized into three soil layers. Here, we further discretized the HYPE subsurface domain to accommodate up to seven soil layers to improve the representation of subsurface thermodynamics and water transfer more accurately. Soil moisture data from different locations across NCRB are collected from 2013 to 2017 for model calibration. We use multi-objective optimization (MOO) to account for streamflow and soil moisture variability and improve the model fidelity at a continental scale.
New hydrological insights
Our study demonstrates that MOO significantly improves soil moisture simulation from the median Kling Gupta Efficiency (KGE) of 0.21–0.66 without deteriorating the streamflow performance. Streamflow and soil moisture simulation performance improvements are statistically insignificant between the original three-layer and seven-layer discretization of HYPE. However, the finer discretization model shows improved simulation in sub-surface components such as the evapotranspiration when verified against reanalysis products, indicating a 12 % underestimation of evapotranspiration from the three-layer HYPE model. The improvement of the discretized HYPE model and simulating the soil temperature at finer vertical resolution makes it a prospective model for permafrost identification and climate change analysis.
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