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新疆焉耆盆地膜下滴灌以来生态环境与灌溉行为演变研究

Study on the evolution of ecological environment and irrigation behavior since mulched drip irrigation in Yanqi basin, Xinjiang.

作者信息

Wang Yongpeng, Yang Pengnian, Wang Huanbo, Zhou Long, Li Xin, Li Zhipeng

机构信息

College of Hydraulic and Civil Engineering, Xinjiang Agricultural University, Urumqi, 830052, China.

Xinjiang Key Laboratory of Hydraulic Engineering Security and Water Disasters Prevention, Urumqi, 830052, China.

出版信息

Sci Rep. 2025 Apr 28;15(1):14778. doi: 10.1038/s41598-025-97991-4.

DOI:10.1038/s41598-025-97991-4
PMID:40295558
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12038004/
Abstract

Analyzing the ecological and behavioral effects of changes in irrigation practices in oases provides valuable insights for water resource management and the sustainable development of oasis agriculture in arid regions. Taking the Yanqi Basin as a case study, this research draws on long-term empirical data and remote sensing information to evaluate the ecological and irrigation behavior effects resulting from shifts in irrigation methods. And explores the deep societal causes behind these behavioral changes. The findings demonstrate: (1). Between 2000 and 2010, the rapid adoption of groundwater extraction and mulched drip irrigation (MDI) technology temporarily alleviated the water supply-demand contradiction. However, from 2010 to 2020, as the adoption of water-saving practices significantly expanded and agricultural irrigation areas grew substantially, the irrigation paradox emerged, where increased efficiency paradoxically led to greater water consumption. (2). From 2000 to 2020, the groundwater table depth in the irrigation district dropped by 8-16 m, total soluble salt content decreased by 2-5 g/L, and soil salinity decreased by 4-12 g/kg. The proportion of severely salinized and saline soil areas fell from 21.74% in 1999 to 9.75% in 2020. The longstanding salinization issues that had plagued the irrigation district were effectively mitigated with the widespread adoption of MDI. (3). The irrigation district's vegetation ecological quality index (VEQI) showed a slow but steady upward trend in cultivated areas over the years. In contrast, natural vegetation areas such as forests and grasslands exhibited an initial increase followed by a decline. The trends in VEQI responded well to changes in irrigation practices. (4). The economic benefits driven by water-saving technologies and the expansion of cultivated land are deep societal factors behind the changes in irrigation behavior. These benefits also fostered improvements in users' understanding and awareness of irrigation practices. The shift in irrigation methods in the Yanqi Basin has led to a decline in groundwater levels, an irrigation paradox, and moderate damage to natural vegetation. However, it has had a significant positive impact on improving regional groundwater quality and mitigating soil salinization. Furthermore, it facilitates the further exploration of regional water conservation potential, enhancing the research on the regional water and soil resource management system.

摘要

分析绿洲灌溉方式变化的生态和行为影响,为干旱地区水资源管理和绿洲农业可持续发展提供了有价值的见解。以焉耆盆地为例,本研究利用长期实证数据和遥感信息,评估灌溉方式转变所产生的生态和灌溉行为影响,并探究这些行为变化背后深层的社会原因。研究结果表明:(1)2000年至2010年,地下水抽取和膜下滴灌(MDI)技术的迅速采用暂时缓解了供水需求矛盾。然而,2010年至2020年,随着节水措施的采用显著扩大且农业灌溉面积大幅增加,灌溉悖论出现,即效率提高却反常地导致用水量增加。(2)2000年至2020年,灌区地下水位下降了8 - 16米,总可溶性盐含量下降了2 - 5克/升,土壤盐分下降了4 - 12克/千克。重度盐碱化和盐碱土面积比例从1999年的21.74%降至2020年的9.75%。随着MDI的广泛采用,长期困扰灌区的盐碱化问题得到有效缓解。(3)多年来,灌区耕地植被生态质量指数(VEQI)呈缓慢但稳定的上升趋势。相比之下,森林和草原等自然植被区则先上升后下降。VEQI趋势对灌溉方式变化反应良好。(4)节水技术和耕地扩张带来的经济效益是灌溉行为变化背后深层的社会因素。这些效益也促进了用户对灌溉方式理解和认识的提高。焉耆盆地灌溉方式的转变导致地下水位下降、出现灌溉悖论以及对自然植被造成一定损害。然而,它对改善区域地下水质量和减轻土壤盐碱化产生了显著的积极影响。此外,它有助于进一步挖掘区域节水潜力,加强对区域水土资源管理系统的研究。

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