Abstract
In the saline water area of our research, deep groundwater was over-pumped for agricultural irrigation which resulted in a decline of the deep groundwater level and an increase in the shallow groundwater table. Soil salination was also aggravated due to the strong evapotranspiration (ET) in the shallow groundwater areas, where ET removes water vapor from the unsaturated zone (ETu), and the groundwater (ETg). Joint utilities of multiple water sources of transferred water and local shallow and deep groundwater are essential for reasonable management of irrigation water. However, it is still difficult to distinguish ETu and ETg in coupled management of unsaturated zone and groundwater, which account for the water balance in utilities of multiple water sources in a regional scale. In this paper, we used an RS-based ETWatch model as a source of evapotranspiration data coupled with UZF-MODFLOW, an integrated hydrological model of the unsaturated–saturated zone, to estimate the ETg and ETu on a regional scale. It was shown that the coupled model (ETWatch-UZF-MODFLOW) avoids the influence of ETu on the groundwater balance calculation and improves the accuracy of the groundwater model. The model was used in the simulation and prediction of groundwater level. The eastern North China Plain (NCP) was selected as the study area where shallow groundwater was saline water and deep groundwater cone existed. We compared four different scenarios of irrigation methods, including current irrigation scenario, use of saline water, limited deep groundwater pumping, use of multiple water sources of transferred water and local groundwater. Results indicate that the total ETg for the four scenarios in the study area from 2013 to 2030 is 119 × 108 m3, 81.9 × 108 m3, 85.0 × 108 m3, and 92.3 × 108 m3, respectively, and the proportion of ETg to total ET was 6.85%, 4.79%, 4.97%, 5.37%. However, in regions where the groundwater depth is less than 3 m, ETg accounts for 12% of the total ET, indicating that groundwater was one of the main sources of evapotranspiration in shallow groundwater depth area.
Highlights
Water scarcity has become the biggest challenge to global agricultural development [1]
We have developed an unsaturated–saturated zone coupled model; the important value of this model is its coupling of remote sensing data to the integrated hydrological model and remote sensing data, which has an irreplaceable advantage in reflecting the spatial heterogeneity of regional models, so the coupled model improves the accuracy of the hydrological model at aregional scale
We developed an ETWatch-unsaturated zone flow (UZF)-MODFLOW coupled model to predict the sustainability of groundwater under the current irrigation strategy (Scenario 1) in the eastern North
Summary
Water scarcity has become the biggest challenge to global agricultural development [1]. With a third of the population in developing countries living in water-scarce areas, fifty-four percent of agriculture is located in water-scarce areas [2,3]. In areas with a shallow groundwater depth, saline water is distributed widely. Evaporation in these areas is much greater than precipitation and irrigation is the only way to sustain crop growth. Joint use of transferred water and local water sources in a saline water area is important for the optimal management of agricultural irrigation imperative
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