改进干湿交替灌溉提高全球水生产力

Yan Bo, Xuhui Wang, Kees Jan van Groenigen, Bruce A. Linquist, Christoph Müller, Tao Li, Jianchang Yang, Jonas Jägermeyr, Yue Qin, Feng Zhou
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引用次数: 0

摘要

水稻是世界上一半人口的主食,但也是谷类作物中水足迹最大的作物。交替湿润和干燥(AWD)是一种很有前景的灌溉策略,可提高水稻的水分生产率(即水稻产量与灌溉用水量之比)。然而,由于对潜在产量损失的担忧以及对水生产率提高的不确定性,其在全球范围内的应用一直受到限制。在此,我们利用 1,187 个对 AWD 和连续淹水条件下水稻产量的配对田间观测数据来量化 AWD 效果(ΔY),结果发现,ΔY 的变化主要是由干旱期最低土壤水势造成的。我们估计,在全球 37% 的水稻灌溉区,尤其是印度、孟加拉国和中国中部地区,实施基于土壤水势的 AWD 计划可提高水分生产率。这些发现凸显了水稻全生育期灌溉在促进更可持续的水稻生产系统方面的潜力,并为全球水稻种植的可持续集约化提供了一条途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Improved alternate wetting and drying irrigation increases global water productivity

Improved alternate wetting and drying irrigation increases global water productivity

Rice is the staple food for half of the world’s population but also has the largest water footprint among cereal crops. Alternate wetting and drying (AWD) is a promising irrigation strategy to improve paddy rice’s water productivity—defined as the ratio of rice yield to irrigation water use. However, its global adoption has been limited due to concerns about potential yield losses and uncertainties regarding water productivity improvements. Here, using 1,187 paired field observations of rice yield under AWD and continuous flooding to quantify AWD effects (ΔY), we found that variation in ΔY is predominantly explained by the lowest soil water potential during the drying period. We estimate that implementing a soil water potential-based AWD scheme could increase water productivity across 37% of the global irrigated rice area, particularly in India, Bangladesh and central China. These findings highlight the potential of AWD to promote more sustainable rice production systems and provide a pathway toward the sustainable intensification of rice cultivation worldwide.

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