Shifting sands to sustainable soils: Spatial dynamics of soil water and salinity in a desert oasis ecotone

IF 5.9 1区农林科学 Q1 AGRONOMY

Agricultural Water Management Pub Date : 2025-05-22 DOI:10.1016/j.agwat.2025.109562

Qiqi Cao , Tao Liu , Jiangbao Xia , Junran Li , Sujith Ravi , Zhiming Xin , Huijie Xiao

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引用次数: 0

Abstract

Understanding the spatiotemporal patterns of soil moisture and salinity dynamics and their governing factors is essential for predicting salinization risks and developing mitigation strategies in arid agricultural landscapes. This study examined the vertical distribution (0–3 m) of soil water content (SWC), electrical conductivity (EC), and pH, and identified their dominant controls across bare sand dunes, nabkha dunes, and croplands of varying cultivation durations (2–5, 12–15, 25–30, and 40–50 years) in a desert–oasis ecotone of northwestern China. The results showed that SWC, EC, and pH generally increased with soil depth and were best described by quadratic or power functions. Bare sand dunes had the lowest values of all three parameters, while EC and pH peaked in nabkha dunes (188.20–636.83 μS·cm^-¹ and 7.88–8.43, respectively), particularly those near the water area, where the early-stage cultivation may be more challenging. Conversion to cropland reduced surface (0–0.4 m) EC and pH by 7.3–34.7 % and 3.9–7.2 %, respectively, after 40–50 years of cultivation, in contrast, subsurface soil layers (0.4–3 m) exhibited stable EC and pH levels after long-term irrigation, with no significant changes between 25–30 and 40–50 years of cultivation (P > 0.05). However, subsurface salinity (0.4–1 m) in newly reclaimed croplands (2–5 years) tended to be higher than that in both nabkha dunes and older croplands, suggesting a potential risk of salinization in the new croplands, which require optimized irrigation. Soil texture was the dominant factor controlling SWC, while cultivation years primarily explained the variation in EC and pH. These findings reveal critical spatiotemporal dynamics in soil water-salt following land use change and offer guidance for optimizing irrigation practices to prevent secondary salinization in arid regions.

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流沙向可持续土壤的转变：荒漠绿洲过渡带土壤水分和盐分的空间动态

了解土壤水分和盐分动态的时空格局及其控制因素对于预测干旱农业景观的盐渍化风险和制定缓解策略至关重要。研究了中国西北荒漠-绿洲过渡带土壤含水量、电导率和pH值的垂直分布（0-3 m），并确定了不同耕作年限（2-5年、12-15年、25-30年和40-50年）在裸沙丘、纳布卡沙丘和农田中的优势控制因子。结果表明，土壤SWC、EC和pH随土壤深度的增加而增加，用二次函数或幂函数来描述最合适。裸沙沙丘的3个参数值均最低，而纳布卡沙丘的EC和pH值最高（分别为188.20 ~ 636.83 μS·cm-¹和7.88 ~ 8.43 μS·cm-¹），特别是靠近水域的沙丘，早期栽培可能更具挑战性。40-50年耕作后，还田土壤表层（0-0.4 m） EC和pH值分别降低了7.3 - 34.7%和3.9-7.2 %，而长期灌溉后，地下土层（0.4 - m） EC和pH值保持稳定，在25-30年和40-50年耕作期间无显著变化（P >； 0.05）。然而，新开垦农田（2-5年）地下盐度（0.4-1 m）高于纳布哈沙丘和老农田，表明新开垦农田存在盐渍化风险，需要优化灌溉。土壤质地是土壤水分含量的主要控制因子，土壤水分含量和土壤ph值的变化主要是由耕作年限决定的。研究结果揭示了土地利用变化后土壤水盐变化的关键时空动态，为优化干旱地区的灌溉方式以防止次生盐渍化提供了指导。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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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.