Modeling and assessing field irrigation water use in a canal system of Hetao, upper Yellow River basin: Application to maize, sunflower and watermelon

•HYDRUS-1D model was modified by coupling with the dualKc approach.•Water–salt fate and yield were simulated for three crops under shallow water table.•Water use was evaluated in a canal system with fragmented crops simultaneously.•New insights were provided for improving water use efficiency and sa...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) 2016-01, Vol.532, p.122-139
Main Authors: Ren, Dongyang, Xu, Xu, Hao, Yuanyuan, Huang, Guanhua
Format: Article
Language:English
Subjects:
Citrullus lanatus
Computer simulation
Crops
Dispersions
DualKc approach
Evaporation
Fragmented fields
Freshwater
Helianthus
HYDRUS-1D
Irrigation
Reuse
River basins
Shallow water table
Sunflowers
Water saving
Water transformation
Zea mays
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Summary:•HYDRUS-1D model was modified by coupling with the dualKc approach.•Water–salt fate and yield were simulated for three crops under shallow water table.•Water use was evaluated in a canal system with fragmented crops simultaneously.•New insights were provided for improving water use efficiency and saving water. Water saving in irrigation is a key issue in the upper Yellow River basin. Excessive irrigation leads to water waste, water table rising and increased salinity. Land fragmentation associated with a large dispersion of crops adds to the agro-hydrological complexity of the irrigation system. The model HYDRUS-1D, coupled with the FAO-56 dual crop coefficient approach (dualKc), was applied to simulate the water and salt movement processes. Field experiments were conducted for maize, sunflower and watermelon crops in the command area of a typical irrigation canal system in Hetao Irrigation District during 2012 and 2013. The model was calibrated and validated in three crop fields using two-year experimental data. Simulations of soil moisture, salinity concentration and crop yield fitted well with the observations. The irrigation water use was then evaluated and results showed that large amounts of irrigation water percolated due to over-irrigation but their reuse through capillary rise was also quite large. That reuse was facilitated by the dispersion of crops throughout largely fragmented field, thus with fields reusing water percolated from nearby areas due to the rapid lateral migration of groundwater. Beneficial water use could be improved when taking this aspect into account, which was not considered in previous researches. The non-beneficial evaporation and salt accumulation into the root zone were found to significantly increase during non-growth periods due to the shallow water tables. It could be concluded that when applying water saving measures, close attention should be paid to cropping pattern distribution and groundwater control in association with irrigation scheduling and technique improvement.
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2015.11.040