Groundwater Renewability Study Based on Tritium (3H) in the Middle and Lower Watershed of Anyang River

doi:10.19657/j.geoscience.1000-8527.2020.066

Abstract

Abstract:

Groundwater renewable ability in the middle and lower watershed of Anyang River are studied by analyzing the tritium concentration of water, groundwater age and mean annual renewal rate (MARR). The MGMTP is employed to reconstruct the ³H concentration of atmospheric precipitation in the study area (1953-2016), whilst the groundwater age and MARR of phreatic water and springs are assessed via Lumped Parameter Modelling (LPM) and the method developed by Le Gal La Shalle et al., respectively. The results indicate that: (1) Phreatic water and springs received atmospheric precipitation recharge over the past 20 years, and the recharge and flow condition of the unconfined groundwater extended widely due to the regional hydrogeological control. (2) The mean residence time of the Xiaonanhai spring is 23 years, associated with 3.6% of MARR and its flux has been attenuating. (3) Unconfined groundwater in the empennage of the Anyang River alluvial/proluvial fan and recharge area has considerable renewable capacity, as it received direct recharge from infiltrated atmospheric precipitation and surface water leakage. Groundwater from the middle zone of the fan to the Beijing-Hongkong-Macao highway is 40-60 years old, and is largely sourced from modern atmospheric precipitation. Nevertheless, that in frontal belt of the fan has very low renewable capacity due to its mixing nature between modern groundwater and older input, with average age not younger than 60 years. (4) Deep confined groundwater in both the eroded hills and alluvial and flood plain is very old and has thus low renewability. This indicates that protection of the Xiaonanhai spring should be increased, and considerable achievement should be obtained in short period of time. The underground water depression cone in the Anyang city urban area has been substantially shrunk by the water supply from the Middle-Route of South to North Water Transfer Project, and the restriction on groundwater exploitation.

Key words: tritium, groundwater age, groundwater renewability, middle and lower watershed of Anyang River

CLC Number:

P641.1
P632

HUANG Xiangui, PING Jianhua, YU Yan, ZHU Yaqiang, ZHANG Min. Groundwater Renewability Study Based on Tritium (³H) in the Middle and Lower Watershed of Anyang River[J]. Geoscience, 2021, 35(03): 693-702.

Figures/Tables 10

References 44

[1]	禹言. 南水北调中线工程受水区地下水库调蓄能力研究[D]. 郑州: 郑州大学, 2018: 15-20, 28.
[2]	段付德, 李文娟. 安阳市地下水可持续利用研究[J]. 河南水利, 2003(3): 11.
[3]	杨德贵, 宋立志, 张国建. 安阳市区地下水动态特征及影响因素分析[J]. 地下水, 2010, 32(5): 107.
[4]	张旭. 基于WPI 体系的安阳市供水安全评价[D]. 郑州: 郑州大学, 2015: 23-24.
[5]	刘峰, 崔亚莉, 张戈, 等. 应用氚和¹⁴C方法确定柴达木盆地诺木洪地区地下水年龄[J]. 现代地质, 2014, 28(6): 1322-1328.
[6]	顾蔚祖, 庞忠和, 王全九, 等. 同位素水文学[M]. 北京: 科学出版社, 2011: 429- 550, 945-1043.
[7]	刘君. 呼和浩特盆地地下水年龄结构与补给流动模式研究[D]. 北京:中国地质科学院, 2016: 35-44.
[8]	CARTWRIGHT I, CENDON D, CURRELL M, et al. A review of radioactive isotopes and other residence time tracers in understanding groundwater recharge: possibilities, challenges, and limitations[J]. Journal of Hydrology, 2017, 555:797-811. DOI URL
[9]	CHAMBERS L A, GOODDY D C, BINLEYET A M, et al. Use and application of CFC-11, CFC-12, CFC-113 and SF₆ as environmental tracers of groundwater residence time: A review[J]. Geoscience Frontiers, 2018, 10(5): 1643-1652. DOI URL
[10]	陈宗宇, 陈京生, 费宇红, 等. 利用氚估算太行山前地下水更新速率[J]. 核技术, 2006, 29(6): 426-431.
[11]	IAEA. Manual on mathematical models in isotope hydrogeology[R]. Vienna:IAEA, 1996: 9-59.
[12]	TURNADGE C, SMERDON B. A review of methods for modelling environmental tracers in groundwater: Advantages of tracer concentration simulation[J]. Journal of Hydrology, 2014, 519:3674-3689. DOI URL
[13]	AMIN I, CAMPANA M. A general lumped parameter model for the interpretation of tracer data and transit time calculation in hydrologic systems[J]. Journal of Hydrology, 1996, 179:1-21. DOI URL
[14]	吴秉钧. 我国大气降水线中氚的数值推算[J]. 水文地质与工程地质, 1986, 13(4): 38-40.
[15]	王瑞久. 山西娘子关泉的地下水储量估算[J]. 水文地质与工程地质, 1984, 11(1): 34-38.
[16]	连炎清. 大气降水氚含量恢复的多元统计学方法——以临汾地区降水量恢复为例[J]. 中国岩溶, 1990(2): 157-166.
[17]	苏小四. 同位素技术在黄河流域典型地区地下水更新能力研究中的应用——以银川平原和包头平原为例[D]. 长春: 吉林大学, 2002: 19-29.
[18]	龙文华, 陈鸿汉, 段青梅, 等. 人工神经网络方法在大气降水氚值恢复中的应用[J]. 地质与资源, 2008, 17(3): 208-212.
[19]	DONEY S C, GLOVER D M, JENKINS W J. A model function of the global bomb tritium distribution in precipitation, 1960—1986[J]. Journal of Geophysical Research, 1992, 97(4): 5481-5492. DOI URL
[20]	章艳红, 叶淑君, 吴吉春. 全球大气降水中年平均氚值的恢复模型[J]. 地质评论, 2011, 57(3): 409-418.
[21]	杨平, 叶淑君. 全球大气降水年平均氚值恢复模型(1960—2014年)[J]. 环境科学学报, 2018, 38(5): 1759-1767.
[22]	GRABCZAK J, RÓẐAÑSKI K, MALOSZEWSK I P, et al. Estimation of the tritium input function with the aid of stable isotopes[J]. CATENA, 1984, 11(2/3): 105-114. DOI URL
[23]	邵益生. 应用环境同位素方法确定泉域岩溶水滞留时间和含水层的参数[J]. 工程勘察, 1987(2): 39-44.
[24]	张坤. 同位素在河南煤矿水文地质条件研究中的应用[D]. 焦作:河南理工大学, 2012: 47-56.
[25]	赵云章, 仝长水, 吴继臣, 等. 豫北平原地下水¹⁴C同位素特征[J]. 工程勘察, 2006(8): 32-34.
[26]	苗晋祥. 基于同位素的豫北平原浅层地下水形成的认识[J]. 水文地质工程地质, 2010, 37(4): 5-11.
[27]	DONG W H, KANG B, DU S H, et al. Estimation of shallow groundwater ages and circulation rates in the Henan Plain, China: CFC and deuterium excess methods[J]. Geoscience Journal, 2013, 17(4): 479-488. DOI URL
[28]	仝晓霞. 氮和氯稳定同位素在豫北平原地下水硝酸盐来源识别中的指示意义[D]. 武汉:中国地质大学(武汉), 2012.
[29]	张敏, 平建华, 禹言, 等. 同位素技术解析安阳河中下游地表水与地下水相互作用[J]. 水文地质工程地质, 2019, 46(6): 24-33.
[30]	范兰池, 石政华, 苗利芳. 安阳河流域水文特性分析[J]. 海河水利, 2009(6): 23-24.
[31]	刘传杰. 泉域地下水数值模拟及泉域保护对策研究[D]. 南京: 河海大学, 2005: 12, 20-21.
[32]	张坤, 张青艳. 河南安阳7·19特大暴雨对地下水动态的影响[J]. 河南水利与南水北调, 2017(1): 10-11.
[33]	CAO X, XU Q, JING Z, et al. Holocene climate change and human impacts implied from the pollen records in Anyang, central China[J]. Quaternary International, 2010, 227:3-9. DOI URL
[34]	JURGENS B C, BÖHLKE J K, EBERTS S M. Tracer LPM (Version 1): An Excel^® workbook for interpreting groundwater age distributions from environmental tracer data[R]. New York:US.Geological Survey Techniques and Methods Report, 2012.
[35]	IAEA. The global network for isotopes in precipitation[DB/OL].[2019-02-06]. https://nucleus.iaea.org/wiser.
[36]	孙琦, 余翔, 周训, 等. 中国西北干旱地区多级洼地地下水环境同位素分布及指示意义[J]. 现代地质, 2011, 25(6): 1195-1200.
[37]	LE GAL LA SHALLE C, MARLIN C, LEDUC C, et al. Renewal rate estimation of groundwater based on radioactive tracers(³H, ¹⁴C) in an unconfined aquifer in semi-arid area, Iullemeden Basin, Niger[J]. Journal of Hydrology, 2001, 245:145-156.
[38]	赵良菊, 妧云峰, 肖洪浪, 等. 氚同位素在黑河流域水循环研究中的应用[J]. 第四纪研究, 2014, 34(5): 959-972.
[39]	田华, 王文科, 荆秀艳, 等. 玛纳斯河流域地下水氚同位素研究[J]. 干旱区资源与环境, 2010, 24(3): 98-102.
[40]	CLARK I D. Groundwater Geochemistry and Isotopes[M]. New York: CRC Press, Taylor & Francis Group, 2015: 153.
[41]	宋丽红, 张国建, 李坷凌, 等. 安阳市小南海泉流量减小的原因分析[J]. 水文地质工程地质, 2003, 30(4): 86-89.
[42]	林云, 曲鹏冲, 吕海新, 等. 太行山东缘典型岩溶泉流量变化特征及规律分析[J]. 中国岩溶, 2018, 37(5): 671-679.
[43]	CLARK I D, FRITZ P. Environmental Isotopes in Hydrogeology[M]. New York: Lewis Publishers, 1997: 172, 177.
[44]	贾秀梅, 孙继朝, 陈玺, 等. 银川平原承压水氢氧同位素组成与¹⁴C年龄分布特征[J]. 现代地质, 2009, 23(1): 15-22.

年份	降水量/mm	氚值/TU	年份	降水量/mm	氚值/TU	年份	降水量/mm	氚值/TU	年份	降水量/mm	氚值/TU
1953	-	17.89	1970	453.87	119.55	1987	542.99	18.99	2004	568.00	8.40
1954	-	199.46	1971	601.63	123.41	1988	539.65	20.66	2005	587.76	9.49
1955	-	28.27	1972	610.54	76.23	1989	536.46	20.62	2006	592.37	11.72
1956	1 019.31	127.30	1973	697.01	79.19	1990	760.90	23.68	2007	507.16	9.24
1957	498.53	81.55	1974	504.43	75.02	1991	485.25	26.18	2008	517.59	9.10
1958	877.69	407.57	1975	513.65	69.86	1992	351.21	21.14	2009	560.17	9.15
1959	642.99	313.34	1976	607.06	54.55	1993	623.61	15.41	2010	588.75	7.81
1960	477.80	86.23	1977	511.03	60.19	1994	719.26	20.93	2011	597.66	8.69
1961	795.83	137.98	1978	379.65	59.25	1995	455.82	22.25	2012	472.82	8.51
1962	575.78	783.05	1979	370.07	32.82	1996	671.42	30.09	2013	480.00	8.66
1963	1 194.67	1923.32	1980	481.73	35.05	1997	291.53	20.55	2014	534.10	8.61
1964	792.86	1226.83	1981	308.63	33.16	1998	625.80	15.22	2015	478.40	8.63
1965	257.74	507.33	1982	744.66	20.69	1999	457.79	9.10	2016	565.55	9.06
1966	416.15	363.83	1983	481.46	18.25	2000	718.47	12.10	2017	522.30	11.00
1967	590.72	172.03	1984	645.85	21.54	2001	554.15	12.21
1968	528.71	143.50	1985	515.20	20.43	2002	330.39	9.78
1969	616.98	138.90	1986	290.69	25.31	2003	780.46	8.99

年份	降水量/mm	氚值/TU	年份	降水量/mm	氚值/TU	年份	降水量/mm	氚值/TU	年份	降水量/mm	氚值/TU
1953	-	17.89	1970	453.87	119.55	1987	542.99	18.99	2004	568.00	8.40
1954	-	199.46	1971	601.63	123.41	1988	539.65	20.66	2005	587.76	9.49
1955	-	28.27	1972	610.54	76.23	1989	536.46	20.62	2006	592.37	11.72
1956	1 019.31	127.30	1973	697.01	79.19	1990	760.90	23.68	2007	507.16	9.24
1957	498.53	81.55	1974	504.43	75.02	1991	485.25	26.18	2008	517.59	9.10
1958	877.69	407.57	1975	513.65	69.86	1992	351.21	21.14	2009	560.17	9.15
1959	642.99	313.34	1976	607.06	54.55	1993	623.61	15.41	2010	588.75	7.81
1960	477.80	86.23	1977	511.03	60.19	1994	719.26	20.93	2011	597.66	8.69
1961	795.83	137.98	1978	379.65	59.25	1995	455.82	22.25	2012	472.82	8.51
1962	575.78	783.05	1979	370.07	32.82	1996	671.42	30.09	2013	480.00	8.66
1963	1 194.67	1923.32	1980	481.73	35.05	1997	291.53	20.55	2014	534.10	8.61
1964	792.86	1226.83	1981	308.63	33.16	1998	625.80	15.22	2015	478.40	8.63
1965	257.74	507.33	1982	744.66	20.69	1999	457.79	9.10	2016	565.55	9.06
1966	416.15	363.83	1983	481.46	18.25	2000	718.47	12.10	2017	522.30	11.00
1967	590.72	172.03	1984	645.85	21.54	2001	554.15	12.21
1968	528.71	143.50	1985	515.20	20.43	2002	330.39	9.78
1969	616.98	138.90	1986	290.69	25.31	2003	780.46	8.99

编号	类型	水位埋深/m	氚值/TU		年龄/a	更新速率 /%	编号	类型	氚值/TU
编号	类型	水位埋深/m	雨季	旱季	年龄/a	更新速率 /%	编号	类型	雨季	旱季
10	泉水	-	8.2	7.1	23.0	3.6	2	地表水	-	5.8
11	泉水	-	-	7.3	23.0	1.9	3	地表水	-	7.8
14	潜水	5.17	9.8	6.7	6.8	9.6	4	地表水	10.3	9.7
16	潜水	6.43	6.4	-	11.9	1.3	5	地表水	8.5	7.2
17	潜水	0	-	7.3	3.8	17.8	6	地表水	-	7.4
26	潜水	14.67	11.7	9.5	5.0	<58.0	7	地表水	-	6.9
44	潜水	15.52	-	6.9	23.4	13.0	8	地表水	-	7.8
1	地表水		8.9	8.0			9	地表水	-	7.1
氚值统计	采样时期	地表水样品数	潜水样品数	泉水样品数	地表水/TU		潜水/TU
	采样时期	地表水样品数	潜水样品数	泉水样品数	分布	平均值	分布	平均值
	雨季	3	3	1	8.5~10.3	9.23±1.17	6.40~11.7	9.30±1.27
	旱季	9	4	2	5.8~9.7	7.52±0.86	6.7~9.5	7.60±0.80

编号	类型	水位埋深/m	氚值/TU		年龄/a	更新速率 /%	编号	类型	氚值/TU
编号	类型	水位埋深/m	雨季	旱季	年龄/a	更新速率 /%	编号	类型	雨季	旱季
10	泉水	-	8.2	7.1	23.0	3.6	2	地表水	-	5.8
11	泉水	-	-	7.3	23.0	1.9	3	地表水	-	7.8
14	潜水	5.17	9.8	6.7	6.8	9.6	4	地表水	10.3	9.7
16	潜水	6.43	6.4	-	11.9	1.3	5	地表水	8.5	7.2
17	潜水	0	-	7.3	3.8	17.8	6	地表水	-	7.4
26	潜水	14.67	11.7	9.5	5.0	<58.0	7	地表水	-	6.9
44	潜水	15.52	-	6.9	23.4	13.0	8	地表水	-	7.8
1	地表水		8.9	8.0			9	地表水	-	7.1
氚值统计	采样时期	地表水样品数	潜水样品数	泉水样品数	地表水/TU		潜水/TU
	采样时期	地表水样品数	潜水样品数	泉水样品数	分布	平均值	分布	平均值
	雨季	3	3	1	8.5~10.3	9.23±1.17	6.40~11.7	9.30±1.27
	旱季	9	4	2	5.8~9.7	7.52±0.86	6.7~9.5	7.60±0.80

编号		氚值/TU				年龄/a			编号	氚值/TU					年龄/a
编号		雨季		旱季		年龄/a			编号	雨季			旱季		年龄/a
13		6.8		5.5		58.8			31	8.6		-			46.6
15		8.5		7.9		46.6			32	-		6.6			41.9
18		8.3		6.8		44.0			33	<1.0		0.5			>64.0
19		8.0		5.9		48.8			34	8.9		6.5			50.8
20		10.3		6.3		55.1			35	5.2		3.6			58.1
21		<1.0		0.5		>64.0			36	4.3		3.5			60.0
22		9.0		8.0		46.6			37	4.0		1.6			>61.0
23		9.6		7.9		47.8			38	6.8		6.0			62.3
24		8.2		6.8		44.0			39	6.5		5.0			47.8
25		10.2		9.2		48.0			40	4.1		4.8			60.6
27		8.6		7.4		44.3			41	5.7		4.0			61.8
28		7.4		6.5		42.0			42	1.7		2.4			>59.0
29		10.9		7.5		42.1			43	3.9		3.7			>56.0
30		10.5		8.4		47.1			45	<1.0		0.5			>64.0
氚值统计	采样时期		样品数		分布范围/TU		平均值 /TU	分布频率
	雨季		27		1.0~ 10.9		7.33± 1.17	<4.0 TU 为19%			4.0~9.0 TU 为62%			>9.0 TU 为19%
	旱季		27		0.5~ 9.2		5.31± 0.76	<4.0 TU 为30%			4.0~9.0 TU 为67%			>9.0 TU 为3%

Groundwater Renewability Study Based on Tritium (³H) in the Middle and Lower Watershed of Anyang River

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