降水对华北农业区地下水保障能力的影响

王电龙; 张光辉; 冯慧敏; 狄帆; 张西珠; 杜旭婷

doi:10.13961/j.cnki.stbctb.2023.04.033

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降水对华北农业区地下水保障能力的影响

试验研究

- 降水对华北农业区地下水保障能力的影响
- Impacts of Precipitation on Groundwater Preservation Capacity of Agricultural Regions in North China
- 水土保持通报 2023年43卷第4期页码：276-282
- 作者机构：
  
  1. 太原工业学院环境与安全工程系,山西,太原,030012
  2. 中国水利水电科学研究院流域水循环与调控国家重点实验室,北京,100086
  3. 中国地质科学院水文地质环境地质研究所,河北,石家庄,050801
  4. 山西农业大学城乡建设学院, 山西太谷,030801
  5. 太原理工大学,山西,太原,030002
- 作者简介：
- 基金信息：
  
  国家自然科学基金项目“气候突变模式下华北农业区地下水保障能力响应特征”(4170226);山西省高等学校科技创新项目(2021L559);太原工业学院青年(后备)学科带头人支持计划项目(202104)
- DOI：10.13961/j.cnki.stbctb.2023.04.033
  中图分类号： S274.3
- 纸质出版：2023
- 稿件说明：
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王电龙, 张光辉, 冯慧敏, 等. 降水对华北农业区地下水保障能力的影响[J]. 水土保持通报, 2023,43(4):276-282.

Wang Dianlong, Zhang Guanghui, Feng Huimin, et al. Impacts of Precipitation on Groundwater Preservation Capacity of Agricultural Regions in North China[J]. Bulletin of Soiland Water Conservation, 2023, 43(4): 276-282.
王电龙, 张光辉, 冯慧敏, 等. 降水对华北农业区地下水保障能力的影响[J]. 水土保持通报, 2023,43(4):276-282. DOI： 10.13961/j.cnki.stbctb.2023.04.033.

Wang Dianlong, Zhang Guanghui, Feng Huimin, et al. Impacts of Precipitation on Groundwater Preservation Capacity of Agricultural Regions in North China[J]. Bulletin of Soiland Water Conservation, 2023, 43(4): 276-282. DOI： 10.13961/j.cnki.stbctb.2023.04.033.

摘要

[目的] 评估降水对华北农业区地下水保障能力的影响，为该区地下水资源可持续利用提供理论依据。[方法] 建立地下水保障能力(F)评价理论体系，采用地学统计、关联度分析等方法，分析降水对地下水保障能力影响的时空特征。[结果] ①随降水量变化，F值空间分布变化明显，多年平均和丰水年以“基本保障”分布为主，枯水年则以“难以保障”为主； ②随降水量变化，不同区位F发生频次亦不同。在燕山山前平原和太行—冀中平原，当降水频率分别＞75%和＞50%时，F值均在0.5以下；太行—豫北平原，当降水频率＜75%时，F值升高至以大于1.0的频次为主；中部—豫北平原，当降水频率＜50%时，F值均增大至1.0以上；当降水频率＜25%时，中部—鲁北平原和滨海平原F值均增大至0.5以上，而中部—冀中平原只有少数年份F大于0.5。[结论] 降水是影响地下水保障能力的重要因素，对平水年和枯水年仍为“较高保障”的区域可适当扩大农业种植规模，对丰水年为“难以保障”和“较低保障”的区域，应适当压缩农业种植规模。

Abstract

[Objective] The impacts of precipitation on the groundwater preservation capacity for agricultural regions in North China were studied in order to provide a theoretical basis for the sustainable use of groundwater resources in this region. [Methods] We established a theoretical system for evaluating groundwater preservation capacity (F) and determined the influence of precipitation changes on F value in agricultural regions of North China using methods such as geoscience statistics and correlation analysis. [Results] ① The spatial distribution of F value changed dramatically as precipitation changed. The multi-year average and wet years were dominated by the “basic guarantee” distribution

while the dry years were dominated by the “difficult to guarantee” distribution; ② As precipitation changed

the frequency of F value also varied in different locations. In the Yanshan Plain and the Taihang-Hebei Plain

when the precipitation frequency was greater than 75% and 50%

respectively

the F value was less than 0.5; in the Taihang-Henan Plain

when the precipitation frequency was less than 75%

the F value was greater than 1.0; in the Central Henan Plain

when the precipitation frequency was less than 50%

the F value increased to 1.0; in the Central Shandong Plain and Littoral Plain

when the precipitation frequency was less than 25%

the F value was greater than 0.5; in the Central Hebei Plain

there were only a few years where the F value was greater than 0.5. [Conclusions] Precipitation is an important factor that affects groundwater preservation capacity. For areas that can be “highly preserved” even during normal and dry years

the scale of agricultural planting can be appropriately expanded to ensure ample food production. However

for areas that are “difficult to preserve” and have “lower preservation” capacity during wet years

the scale of agricultural planting should be appropriately reduced to alleviate the pressure of groundwater overexploitation.

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