Deficit irrigation combined with a high planting density optimizes root and soil water–nitrogen distribution to enhance cotton productivity in arid regions

IF 5.6 1区 农林科学 Q1 AGRONOMY
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Abstract

Context

Increasing the cotton planting density can reduce irrigation while maintaining the seed cotton yield. However, the underlying physiological and ecological mechanisms remain unclear. We hypothesized that increasing the planting density and reducing irrigation would promote dynamic consistency in the distribution of the roots, soil water, and nitrogen, leading to improved cotton water productivity and ultimately achieving a stable seed cotton yield.

Method

To test this hypothesis, a 3-year field experiment (2019–2021) was conducted in Xinjiang, China. The main plots were subjected to 3 irrigation levels based on crop evapotranspiration (ETc): 0.6 (deficit), 0.8 (typical), and 1.0 ETc (adequate). Subplots were planted at 3 densities: 13.5 (low), 18.0 (typical), and 22.5 plants m−2 (high).

Results

Under typical irrigation conditions, the seed cotton yield was significantly higher at a typical planting density than at a low or high planting density. However, with adequate irrigation, a low planting density resulted in a higher yield, while a high planting density combined with adequate irrigation reduced the yield by 14.7 % compared with typical conditions (typical irrigation + typical planting density). Under deficit irrigation, the seed cotton yield at a high planting density was 9.2–23.5 % higher than that at a low or typical planting density, achieving yield stability with 20 % water saving. The dry matter accumulation and harvest index showed no significant differences between typical irrigation + typical planting density and deficit irrigation + high planting density. Deficit irrigation combined with a high planting density resulted in a higher overlap rate of the root distribution area, soil water consumption area, and nitrate nitrogen consumption area, leading to higher water productivity than that of other density and irrigation combinations.

Conclusion

Deficit irrigation combined with a high planting density can reduce water input by 20 % without sacrificing cotton yield, likely because of increased water productivity through the enhanced dynamic consistency of root distribution and soil water-nitrogen consumption. These findings provide valuable ecological and physiological insights for achieving water savings without compromising yield in arid and water-scarce regions.

缺水灌溉与高密度种植相结合,优化了根系和土壤水氮分布,提高了干旱地区的棉花产量
背景提高棉花种植密度可以减少灌溉,同时保持籽棉产量。然而,其背后的生理和生态机制仍不清楚。我们假设,增加种植密度并减少灌溉会促进根系、土壤水分和氮素分布的动态一致性,从而提高棉花水分生产率,最终实现稳定的籽棉产量。根据作物蒸散量(ETc)对主要地块进行了 3 种灌溉水平的试验:0.6(亏缺)、0.8(典型)和 1.0 ETc(充足)。子地块以 3 种密度种植:结果在典型灌溉条件下,典型种植密度的籽棉产量明显高于低种植密度或高种植密度。然而,在充足灌溉条件下,低种植密度产量更高,而高种植密度加上充足灌溉,产量比典型条件(典型灌溉+典型种植密度)减少了 14.7%。在缺水灌溉条件下,高种植密度的籽棉产量比低种植密度或典型种植密度的籽棉产量高出 9.2-23.5 %,在节水 20 % 的情况下实现了稳产。干物质积累和收获指数在典型灌溉+典型种植密度和亏缺灌溉+高种植密度之间无显著差异。与其他密度和灌溉组合相比,亏缺灌溉与高种植密度相结合可提高根系分布区、土壤水分消耗区和硝态氮消耗区的重叠率,从而提高水分生产率。这些发现为干旱缺水地区在不影响产量的情况下实现节水提供了宝贵的生态和生理启示。
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来源期刊
Field Crops Research
Field Crops Research 农林科学-农艺学
CiteScore
9.60
自引率
12.10%
发文量
307
审稿时长
46 days
期刊介绍: Field Crops Research is an international journal publishing scientific articles on: √ experimental and modelling research at field, farm and landscape levels on temperate and tropical crops and cropping systems, with a focus on crop ecology and physiology, agronomy, and plant genetics and breeding.
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