Abstract
To investigate the effects of alternate partial root-zone irrigation (APRI) and water deficit at different growth stages on maize growth, physiological characteristics, the grain yield, and the water use efficiency (WUE), a pot experiment was conducted under a mobile automatic rain shelter. There were two irrigation methods, i.e., conventional irrigation (CI) and APRI; two irrigation levels, i.e., mild deficit irrigation (W1, 55%~70% FC, where FC is the field capacity) and serious deficit irrigation (W2, 40%~55% FC); and two deficit stages, i.e., the seedling (S) and milking stage (M). Sufficient irrigation (W0: 70%~85% FC) was applied throughout the growing season of maize as the control treatment (CK). The results indicated that APRI and CI decreased the total water consumption (ET) by 34.7% and 23.8% compared to CK, respectively. In comparison to CK, APRI and CI increased the yield-based water use efficiency (WUEY) by 41% and 7.7%, respectively. APRI increased the irrigation water efficiency (IWUE) and biomass-based water use efficiency (WUEB) by 8.8% and 25.5% compared to CK, respectively. Additionally, ASW1 had a similar grain yield to CK and the largest harvest index (HI). However, the chlorophyll and carotenoid contents were significantly reduced by 13.7% and 23.1% under CI, and by 11.3% and 20.3% under APRI, compared to CK, respectively. Deficit irrigation at the milking stage produced a longer tip length, resulting in a lower grain yield. Based on the entropy weight method and the technique for order preference by similarity to an ideal solution (TOPSIS) method, multi-objective optimization was obtained when mild deficit irrigation (55%~70% FC) occurred at the seedling stage under APRI.
Highlights
In light of the current pressure on increasing crop production, establishing a highyield and water-saving agricultural water use strategy to achieve highly efficient agricultural water use has become a priority for the sustainable development of agriculture in China [1,2,3,4]
We aimed to investigate the responses of water stress-induced physiology, growth, and grain yield to two irrigation levels at different growth stages of maize through a pot experiment under alternate partial root-zone irrigation (APRI)
APRI at M decreased them by 18.21%, 30.23%, and −0.28%, respectively, and APRI at S decreased them by 29.49%, 41.48%, and 13.4%, respectively
Summary
In light of the current pressure on increasing crop production, establishing a highyield and water-saving agricultural water use strategy to achieve highly efficient agricultural water use has become a priority for the sustainable development of agriculture in China [1,2,3,4]. According to the needs of various plants and their growth conditions, accurate estimation of the water demand and the use of irrigation schedules will improve the water use efficiency (WUE) [5]. PRI includes alternate partial root-zone irrigation (APRI) and fixed partial root-zone irrigation (FPRI) [6]. It can make the horizontal or vertical soil profile in the root layer either dry or wet. WUE can be increased without sacrificing the amount of photosynthate by regulating the function of plant stomata and the root system in response to drought stress [7]
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