Changes in root growth and water uptake contribute to the yield and water productivity improvement in winter wheat during the past three decades: A case study in the North China Plain

IF 5.9 1区农林科学 Q1 AGRONOMY

Agricultural Water Management Pub Date : 2025-04-12 DOI:10.1016/j.agwat.2025.109482

Haotian Li , Na Liu , Liwei Shao , Xiuwei Liu , Hongyong Sun , Suying Chen , Xiying Zhang

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Abstract

Over the past three decades the yield and water productivity (WP) of winter wheat have significantly improved in the North China Plain (NCP). The contribution of root systems to these improvements should be understood to develop future strategies for breeding and field management. Continuous root sampling and soil water monitoring were conducted for a long-term irrigation experiment on winter wheat from 1992 to 2023 at the Luancheng Agroecological Experimental Station in the NCP. Three irrigation treatments were selected to represent different water supply conditions, i.e. severe water deficit (SD, no irrigation), moderate water deficit (MD, irrigation of 120–180 mm) and adequate water supply (AW, irrigation of 240–335 mm). For winter wheat, yield increased averagely by 35.0 %, 35.1 % and 42.9 % on average, and WP increased by 19.2 %, 23.2 % and 19.3 % under SD, MD and AW, respectively, from 1992–2023. Corresponding to the improvements in yield and WP, the total root length (TRL) at maturity was decreased by 6.6 %, 7.8 % and 26.2 % under SD, MD and AW, respectively. The reduction in the root length density (RLD) of the 0–40 cm soil layer was 47.4 %, which corresponded to an increase in RLD of 27.7 % in the 40–100 cm layer and 17.5 % in the 100–200 cm layer on average under the three water supply conditions. Redundant root growth in the shallow soil profile decreased without affecting soil water use in the deep soil layer: the root efficiency in water uptake (RE) continuously increased at a rate of 0.30–0.51 10⁻³ m³ km⁻¹ yr⁻¹, and the proportion of soil water depletion that contributed to crop evapotranspiration during the reproductive stage of winter wheat increased from 50.9 %–72.8 % in 1992–1999 to 61.1–78.1 % in 2010–2023 under the three water supply conditions. Optimized distribution of seasonal evapotranspiration increased biomass allocation to grains by 30.0 % for SD, 17.5 % for MD, and 27.0 % for AW from the 1992–2023, whereas the root: shoot ratio (R/S) decreased by 17.0 % for SD, 25.3 % for MD and 22.4 % for AW on average. The results suggest that reducing redundant root growth in the shallow soil profile without affecting soil water use in the deep soil profile could result in a relatively high RE combined with relatively low R/S, thereby reducing root carbohydrate consumption and improving the overall yield and WP of winter wheat.

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近30年来冬小麦根系生长和水分吸收变化对产量和水分生产力的影响——以华北平原为例

在过去的三十年里，华北平原（NCP）冬小麦的产量和水分生产率（WP）都有了显著提高。要制定未来的育种和田间管理战略，就必须了解根系对这些提高的贡献。从 1992 年到 2023 年，在华北平原栾城农业生态试验站对冬小麦的长期灌溉试验进行了连续根系取样和土壤水分监测。试验选择了三种灌溉处理来代表不同的供水条件，即严重缺水（SD，不灌溉）、中度缺水（MD，灌溉120-180毫米）和充足供水（AW，灌溉240-335毫米）。1992-2023年，在SD、MD和AW条件下，冬小麦平均产量分别增加了35.0%、35.1%和42.9%，可湿性粉剂分别增加了19.2%、23.2%和19.3%。与产量和可湿性粉剂的提高相对应，SD、MD 和 AW 下成熟时的总根长（TRL）分别减少了 6.6 %、7.8 % 和 26.2 %。在三种供水条件下，0-40 厘米土层的根长密度（RLD）减少了 47.4%，而 40-100 厘米土层的根长密度平均增加了 27.7%，100-200 厘米土层的根长密度平均增加了 17.5%。浅层土壤剖面多余根系生长减少，但不影响深土层土壤水分利用：根系吸水效率（RE）以 0.30-0.51 10-3 m3 km-1 yr-1 的速率持续增加，在三种供水条件下，冬小麦生育期土壤水分耗损占作物蒸散量的比例从 1992-1999 年的 50.9%-72.8% 增加到 2010-2023 年的 61.1-78.1%。1992-2023年，优化的季节蒸散分配使谷物生物量分配增加了30.0%（SD）、17.5%（MD）和27.0%（AW），而根：芽比（R/S）平均下降了17.0%（SD）、25.3%（MD）和22.4%（AW）。结果表明，在不影响深层土壤水分利用的情况下，减少浅层土壤剖面中多余的根系生长，可使RE相对较高，R/S相对较低，从而减少根系碳水化合物的消耗，提高冬小麦的总体产量和可湿性粉剂。

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来源期刊

Agricultural Water Management 农林科学-农艺学

CiteScore

12.10

自引率

14.90%

发文量

648

审稿时长

4.9 months

期刊介绍： Agricultural Water Management publishes papers of international significance relating to the science, economics, and policy of agricultural water management. In all cases, manuscripts must address implications and provide insight regarding agricultural water management.