SENSITIVITY OF THE HYDRUS-1D MODEL TO CHANGES IN HYDRODYNAMIC PARAMETERS IN YELLOW LATOSOL

A variance-based global sensitivity analysis (extended Fourier amplitude sensitivity test, EFAST) was applied to the Feddes module of the HYDRUS-1D model, and the sensitivity indices including both main and total effects of actual root water uptake (RWUa) to seven Feddes parameters were quantified at different growth stages of sunflower (Helianthus annuus L.): seedling, bud, flowering and maturity. The effects of soil salinity, climate conditions, and crop root growth on parameter sensitivity were explored by analysing three precipitation frequencies and two maximum root depths across four field locations with different soil salinity levels in China’s sunflower-growing regions. Uncertainties for RWUa were evaluated at four stages with varying Feddes parameters for different field locations, precipitation frequencies and maximum root depths. We found that the water stress factor concerning ceasing root water uptake (h4), and two salt stress factors ht and Sp, indicating the salinity threshold and the slope of the curve determining the fractional decline in root water uptake per unit increase in salinity below the threshold, respectively, were three most important Feddes parameters for RWUa estimation in HYDRUS-1D. In addition, the effects of soil salinity and precipitation frequencies were stronger than maximum root depth on the order of the parameters’ impacts on RWUa. Our study suggested that h1, h2, h3h, and h3l might be determined by an economical method (e.g. literature review) in saline soils with limited observations, but it is better to calibrate wilting point (h4) and salt stress parameters (ht and Sp) based on local measurements.

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Estimating the Root Water Uptake of Surface-Irrigated Apples Using Water Stable Isotopes and the Hydrus-1D Model

Water ◽

10.3390/w10111624 ◽

2018 ◽

Vol 10 (11) ◽

pp. 1624 ◽

Cited By ~ 5

Author(s):

Lijian Zheng ◽

Juanjuan Ma ◽

Xihuan Sun ◽

Xianghong Guo ◽

Qiyun Cheng ◽

...

Keyword(s):

Stable Isotopes ◽

Water Use Efficiency ◽

Water Use ◽

Water Uptake ◽

Root Water Uptake ◽

Surface Irrigation ◽

Apple Trees ◽

1D Model ◽

Use Efficiency ◽

Hydrus 1D

The future production of irrigated fruit orchards in the Loess Plateau of China is threatened by a shortage of freshwater. To improve water use efficiency under conditions where irrigation is limited, it is necessary to quantify the root water uptake (RWU) of apple trees. The RWU of apple trees was estimated under surface irrigation using water stable isotope technology and the Hydrus-1D model. Using the Romero-Saltos and IsoSource models, the stable isotopes of water in stems, different soil depths, and different precipitation were analyzed in a 5-year-old dwarfing apple orchard during two seasons 2016 and 2017. Hydrus-1D model was able to simulate the RWU of apple using the maximum coefficient of determination (0.9), providing a root mean square error of 0.019 cm3 cm−3 and a relative error of 2.25%. The results showed that the main depth of RWU ranged from 0–60 cm during the growth season, with the main contribution occurring in the 0–40 cm depth. These findings indicated that reducing the traditional surface irrigation depth will be important for improving the irrigation water use efficiency.

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Water budget components estimation for a mature citrus orchard of southern China based on HYDRUS-1D model

Agricultural Water Management ◽

10.1016/j.agwat.2020.106426 ◽

2021 ◽

Vol 243 ◽

pp. 106426

Author(s):

Anguo Tu ◽

Songhua Xie ◽

Minghao Mo ◽

Yuejun Song ◽

Ying Li

Keyword(s):

Water Budget ◽

Southern China ◽

Citrus Orchard ◽

1D Model ◽

Hydrus 1D

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Risk evaluation of radionuclides contamination on soil and groundwater under different scenarios simulating by HYDRUS-1D

10.5194/egusphere-egu21-1209 ◽

2021 ◽

Author(s):

Liu Wenxiang ◽

Yu Hanqing ◽

Lu Yang

Keyword(s):

Water Content ◽

Radioactive Contamination ◽

Soil Depth ◽

Residual Water ◽

High Concentration ◽

Predictive Values ◽

Lysimeter Experiment ◽

Farmland Soil ◽

1D Model ◽

Hydrus 1D

A large number of radionuclides, produced by nuclear accidents or nuclear waste, may cause radioactive contamination in the agricultural and aquatic ecosystems. Under these circumstances, it is necessary to optimize the remediation of agricultural areas polluted by radionuclides using innovative monitoring and prediction techniques. To mitigate radioactive contamination in farmland soil and effectively protect groundwater, some measures should be taken against on field investigation, laboratory experiment and model prediction. In this study, the HYDRUS-1D model was used to simulate the vertical migration of 137Cs and 60Co in farmland soil in northern China calibrating by the soil lysimeter experiment, and the scenario simulations of 137Cs and 60Co migration were conducted under different radioactive levels. Results showed that the order of sensitivity in saturated water content (&#952;s), residual water content(&#952;r), saturated hydraulic conductivity(Ks) and distribution coefficient (Kd) applied in HYDRUS 1D model was Kd > &#952;s > &#952;r >Ks. The simulated concentrations &#8203;&#8203;of 137Cs and 60Co in Brown soil and Aeolian sandy soil on day 175 and 355 were significantly positively correlated with the measured values&#8203;&#8203; (r>0.90, p<0.01). The verification results showed that the predictive values on the 577th day were also significant positive correlated with the measured values &#8203;&#8203;(r>0.90, p<0.01). The RMSE, CRM and NRMSE calculating by simulated and measured values &#8203;&#8203;of 137Cs and 60Co in soil were very small, indicating that HYDRUS 1D can be used to simulate the migration of radionuclides in farmland soil. Scenarios simulation results revealed that radionuclides were concentrated in the surface layer within 5 cm, but the migration depth has exceed 10 cm soil depth, and even reaches up to 23.5 cm depth at high concentration level. The surface soil should be cleaned timely to protect groundwater with high level from radioactive contamination and further study should be done about horizontal transport and numerical simulation.

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