华北“23·7”强降雨事件对不同埋深地下水的补给机理:以雄安新区为例

doi:10.13745/j.esf.sf.2024.6.34

地学前缘 ›› 2025, Vol. 32 ›› Issue (1): 432-439.DOI: 10.13745/j.esf.sf.2024.6.34

华北“23·7”强降雨事件对不同埋深地下水的补给机理:以雄安新区为例

欧阳恺皋¹(), 蒋小伟¹^,^*(), 杜亚楠², 张志远¹, 韩鹏飞¹, 吴业楠¹, 王旭升¹

1.中国地质大学(北京)地下水循环与环境演化教育部重点实验室, 北京 100083
2.雄安城市规划设计研究有限公司, 河北保定 071700

收稿日期:2024-02-17 修回日期:2024-04-23 出版日期:2025-01-25 发布日期:2025-01-15
通信作者: *蒋小伟(1982—),男,教授,博士生导师,主要从事地下水循环领域的教学与科研工作。E-mail: jxw@cugb.edu.cn
作者简介:欧阳恺皋(1999—),男,博士研究生,水利工程专业,主要从事包气带水循环方面研究工作。E-mail: 3005220022@email.cugb.edu.cn
基金资助:
科学技术部科技创新专项(2022XACX0900);国家自然科学基金项目(42402251)

Mechanism of groundwater recharge at different depths during the “23·7” heavy rainfall event in North China: A case study of Xiong’an New Area

OUYANG Kaigao¹(), JIANG Xiaowei¹^,^*(), DU Yanan², ZHANG Zhiyuan¹, HAN Pengfei¹, WU Yenan¹, WANG Xusheng¹

1. MOE Key Laboratory of Groundwater Circulation and Environmental Evolution, China University of Geosciences (Beijing), Beijing 100083, China
2. Xiong’an Urban Planning and Design Institute Co., Ltd., Baoding 071700, China

Received:2024-02-17 Revised:2024-04-23 Online:2025-01-25 Published:2025-01-15

摘要/Abstract

摘要：

降雨能否穿透厚包气带到达潜水面是地下水补给领域争议较大的问题。华北平原“23·7”极端降雨事件相当于华北平原的一次大型入渗试验,为分析潜水埋深如何控制地下水补给提供了契机。本研究以雄安新区白洋淀周边潜水浅埋区4口自动监测井和容城县境内潜水深埋区6口自动监测井为例,分析不同埋深地下水对2023年3日内累积降雨量为289.2 mm的极端降雨事件的响应规律。在潜水浅埋区,暴雨开始后约16 h垂向入渗至潜水面,潜水抬升幅度达1.36~1.79 m;在潜水深埋区,暴雨后河水水位迅速抬升并引发渗漏形成水丘,在潜水回水作用下离南拒马河距离小于6 km的潜水位以较快速度抬升1.38~3.67 m。本研究表明,降雨沿着包气带的垂向入渗是潜水浅埋区地下水的补给来源,暴雨后河水入渗引发的潜水回水是河道附近潜水深埋区地下水补给的主要来源。本文加深了对不同埋深潜水补给机理的认识,对今后分析华北平原乃至其他地下水超采区的水位回升控制机理、生态补水效果具有重要指导意义。

关键词: 地下水补给, 潜水回水, 生态补水, 厚包气带, 白洋淀

Abstract:

The question of whether rainfall can penetrate a thick unsaturated zone to reach the water table has long been a contentious issue in the field of groundwater recharge. The extreme rainfall event that occurred in the North China Plain from July 23rd to 27th, 2023, equivalent to a large-scale infiltration experiment, provided a valuable opportunity to analyze how groundwater recharge is influenced by the depth to the water table. This study focuses on the Baiyangdian region in the Xiong’an New Area, examining the response patterns of groundwater at different depths during this extreme rainfall event, which delivered a cumulative rainfall of 289.2 mm over three days. Data were collected from four automated monitoring wells in the shallow water table area around Baiyangdian and six automated monitoring wells in the deep water table area within Rongcheng County. In the shallow water table area, vertical infiltration reached the water table approximately 16 hours after the onset of the storm, causing the water table to rise by 1.36 to 1.79 meters. In the deep water table area, river water levels rose rapidly after the storm, leading to leakage that formed a groundwater mound. Due to the backwater effect, groundwater levels within 6 km of the Nanjuhe River rose rapidly by 1.38 to 3.67 meters. This study demonstrates that vertical infiltration through the unsaturated zone is the primary source of groundwater recharge in shallow water table areas. In contrast, in deep water table areas near river channels, post-storm river infiltration and the resulting backwater effect are the main sources of groundwater recharge. These findings improve the understanding of groundwater recharge mechanisms at varying depths and provide valuable insights for analyzing water table recovery processes and the effects of ecological water replenishment in the North China Plain and other regions facing groundwater overexploitation.

Key words: groundwater recharge, phreatic backwater, ecological water replenishment, thick vadose zone, Baiyangdian Lake

中图分类号:

P641
P339

欧阳恺皋, 蒋小伟, 杜亚楠, 张志远, 韩鹏飞, 吴业楠, 王旭升. 华北“23·7”强降雨事件对不同埋深地下水的补给机理:以雄安新区为例[J]. 地学前缘, 2025, 32(1): 432-439.

OUYANG Kaigao, JIANG Xiaowei, DU Yanan, ZHANG Zhiyuan, HAN Pengfei, WU Yenan, WANG Xusheng. Mechanism of groundwater recharge at different depths during the “23·7” heavy rainfall event in North China: A case study of Xiong’an New Area[J]. Earth Science Frontiers, 2025, 32(1): 432-439.

图/表 7

参考文献 30

[1]	GLEESON T, WADA Y, BIERKENS M F P, et al. Water balance of global aquifers revealed by groundwater footprint[J]. Nature, 2012, 488(7410): 197-200.
[2]	LI P Y, QIAN H. Water resources research to support a sustainable China[J]. International Journal of Water Resources Development, 2018, 34(3): 327-336.
[3]	HERRERA-GARCÍA G, EZQUERRO P, TOMÁS R, et al. Mapping the global threat of land subsidence[J]. Science, 2021, 371(6524): 34-36.
[4]	SU G L, WU Y Q, ZHAN W, et al. Spatiotemporal evolution characteristics of land subsidence caused by groundwater depletion in the North China Plain during the past six decades[J]. Journal of Hydrology, 2021, 600: 126678.
[5]	于开宁, 廖安然. 基于生态位理论的河北平原地下水开采潜力评价[J]. 地学前缘, 2018, 25(1): 259-266. DOI
[6]	曹国亮. 华北平原地下水系统变化规律研究[D]. 北京: 中国地质大学(北京), 2013.
[7]	ALLEY W M, HEALY R W, LABAUGH J W, et al. Flow and storage in groundwater systems[J]. Science, 2002, 296(5575): 1985-1990. DOI PMID
[8]	YANG W T, LONG D, SCANLON B R, et al. Human intervention will stabilize groundwater storage across the North China Plain[J]. Water Resources Research, 2022, 58(2): e2021wr030884.
[9]	水利部. 水利部财政部国家发展改革委农业农村部关于印发《华北地区地下水超采综合治理行动方案》的通知[A]. 北京: 水利部, 2019.
[10]	MTHEMBU PP, ELUMALAI V, SENTHILKUMAR M, et al. Investigation of geochemical characterization and groundwater quality with special emphasis on health risk assessment in alluvial aquifers, South Africa[J]. International Journal of Environmental Science and Technology, 2021, 18(12): 3711-3730.
[11]	PONNUSAMY D, ELUMALAI V. Determination of potential recharge zones and its validation against groundwater quality parameters through the application of GIS and remote sensing techniques in uMhlathuze catchment, Kwa Zulu-Natal, South Africa[J]. Chemosphere, 2022, 307: 136121.
[12]	康宏志, 陈亮, 郭祺忠, 等. 海绵城市建设地下水补给计算研究进展[J]. 地学前缘, 2019, 26(6): 58-65. DOI
[13]	杨永辉, 郝小华, 曹建生, 等. 太行山山前平原区地下水下降与降水、作物的关系[J]. 生态学杂志, 2001, 20(6): 4-7, 15.
[14]	张光辉, 费宇红, 申建梅, 等. 降水补给地下水过程中包气带变化对入渗的影响[J]. 水利学报, 2007, 38(5): 611-617.
[15]	杨会峰, 白华, 程彦培, 等. 基于氯离子示踪法深厚包气带地区地下水补给特征[J]. 南水北调与水利科技(中英文), 2022, 20(1): 30-39.
[16]	薛禹群, 朱学愚. 地下水动力学[M]. 北京: 地质出版社, 1979.
[17]	周志芳, 王锦国. 地下水动力学[M]. 北京: 科学出版社, 2013.
[18]	张文喆, 王锦国, 徐烁. 河水位连续变化条件下潜水回水范围计算[J]. 水资源保护, 2013, 29(6): 41-43, 48.
[19]	胡立堂, 郭建丽, 张寿全, 等. 永定河生态补水的地下水位动态响应[J]. 水文地质工程地质, 2020, 47(5): 5-11.
[20]	刘家宏, 梅超, 王佳, 等. 北京市门头沟流域“23·7” 特大暴雨洪水过程分析[J]. 中国防汛抗旱, 2023, 33(9): 50-55.
[21]	李海明, 李梦娣, 肖瀚, 等. 天津平原区浅层地下水水化学特征及碳酸盐风化碳汇研究[J]. 地学前缘, 2022, 29(3): 167-178. DOI
[22]	侯国华, 高茂生, 叶思源, 等. 黄河三角洲浅层地下水盐分来源及咸化过程研究[J]. 地学前缘, 2022, 29(3): 145-154. DOI
[23]	水利部.水利部办公厅关于印发《2019年度华北地区地下水超采综合治理河湖生态补水方案及试点河段后续补水计划》的通知[A]. 北京: 水利部, 2019.
[24]	SHAH N, NACHABE M, ROSS M. Extinction depth and evapotranspiration from ground water under selected land covers[J]. Groundwater, 2007, 45(3): 329-338. PMID
[25]	ZHAO K Y, JIANG X W, WANG X S, et al. Restriction of groundwater recharge and evapotranspiration due to a fluctuating water table: a study in the Ordos Plateau, China[J]. Hydrogeology Journal, 2021, 29(2): 567-577.
[26]	SHI J X, JIANG X W, ZHANG Z Y, et al. Interaction of focused recharge and deep groundwater discharge near a wetland: a study in the Ordos Basin, China[J]. Journal of Hydrology, 2023, 626: 130361.
[27]	张蔚榛. 地下水非稳定流计算和地下水资源评价[M]. 武汉: 武汉大学出版社, 2013.
[28]	CAO G L, ZHENG C M, SCANLON B R, et al. Use of flow modeling to assess sustainability of groundwater resources in the North China Plain[J]. Water Resources Research, 2013, 49(1): 159-175.
[29]	QIN H H, CAO G L, KRISTENSEN M, et al. Integrated hydrological modeling of the North China Plain and implications for sustainable water management[J]. Hydrology and Earth System Sciences, 2013, 17(10): 3759-3778.
[30]	MARTINSEN G, HE X, KOCH J, et al. Large-scale hydrological modeling in a multi-objective uncertainty framework-assessing the potential for managed aquifer recharge in the North China Plain[J]. Journal of Hydrology: Regional Studies, 2022, 41: 101097.

本文编号	位置	井编号	井深/m	离河(湖)距离/km	初始埋深/m	初始高程/m
D1	容城东北1	RZ9-2	58	0.99	5.94	6.81
D2	容城东北2	RCJ8	22	1.23	6.27	6.43
D3	容城北	RCJ2	20	2.53	10.90	4.35
D4	容城县城	RCJ5	30	4.85	12.28	-0.76
D5	容城西北	RCJ1	20	5.91	17.78	-1.38
D6	容城西	RCJ3	29	10.40, 2.85	18.41	-6.23
S1	藻苲淀周边	AXJ1	10	1.54	1.46	4.39
S2	小白洋淀周边	AXJ9	35	1.83	1.56	5.55
S3	捞王淀周边1	AXJ2	10	0.73	1.64	2.97
S4	捞王淀周边2	XXJ17	27	0.86	1.74	3.88

本文编号	位置	井编号	井深/m	离河(湖)距离/km	初始埋深/m	初始高程/m
D1	容城东北1	RZ9-2	58	0.99	5.94	6.81
D2	容城东北2	RCJ8	22	1.23	6.27	6.43
D3	容城北	RCJ2	20	2.53	10.90	4.35
D4	容城县城	RCJ5	30	4.85	12.28	-0.76
D5	容城西北	RCJ1	20	5.91	17.78	-1.38
D6	容城西	RCJ3	29	10.40, 2.85	18.41	-6.23
S1	藻苲淀周边	AXJ1	10	1.54	1.46	4.39
S2	小白洋淀周边	AXJ9	35	1.83	1.56	5.55
S3	捞王淀周边1	AXJ2	10	0.73	1.64	2.97
S4	捞王淀周边2	XXJ17	27	0.86	1.74	3.88

编号	初始埋深/m	抬升时刻	滞后于降雨/h	抬升幅度/m	持续时间/h	平均入渗速率/(m·d^-1)
S1	1.46	2023-07-30 8:00	16.5	1.46	58	2.12
S2	1.56	2023-07-30 7:00	15.5	1.36	61	2.42
S3	1.64	2023-07-30 7:00	15.5	1.56	59	2.54
S4	1.74	2023-07-30 8:00	16.5	1.51	68	2.53

编号	初始埋深/m	抬升时刻	滞后于降雨/h	抬升幅度/m	持续时间/h	平均入渗速率/(m·d^-1)
S1	1.46	2023-07-30 8:00	16.5	1.46	58	2.12
S2	1.56	2023-07-30 7:00	15.5	1.36	61	2.42
S3	1.64	2023-07-30 7:00	15.5	1.56	59	2.54
S4	1.74	2023-07-30 8:00	16.5	1.51	68	2.53

井编号	距河流距离/km	初始埋深/m	起始抬升时刻	滞后时间/h	抬升幅度/m	抬升持续时间/h
D1	0.99	5.94	2023-07-30 9:00	17.5	3.30	90
D2	1.23	6.27	2023-07-30 10:00	18.5	1.85	137
D3	2.53	11.04	2023-07-30 11:00	19.5	2.73	255
D4	4.85	12.28	2023-07-30 22:00	30.5	2.75	210
D5	5.91	17.78	2023-07-31 1:00	33.5	1.14	384
D6	10.40, 2.85	18.41	2023-07-30 11:00	19.5	0.30	103

华北“23·7”强降雨事件对不同埋深地下水的补给机理:以雄安新区为例

Mechanism of groundwater recharge at different depths during the “23·7” heavy rainfall event in North China: A case study of Xiong’an New Area

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