Enrichment Mechanism of Deep Groundwater with High Fluoride in Coastal Plains: A Case Study of the Luanhe Delta

doi:10.19657/j.geoscience.1000-8527.2022.029

Abstract

Abstract:

High F^- groundwater has been found in deep aquifers of the coastal plain region, which seriously threatens the domestic water safety. To ascertain its enrichment mechanism, sixty-nine groundwater samples on site were collected for hydrochemical and isotopic analyses of the low- and high-fluoride groundwater. The results show that high fluoride groundwater mainly exists in Na-HCO₃-type groundwater, while the chemical type of low-fluoride groundwater is mainly Ca·Na-HCO₃. Saturation index calculation shows that the groundwater samples are mostly fluorite undersaturated but calcite oversaturated. This indicates that fluorite dissolution is favored with precipitations of Ca²⁺ as calcite, thus leading to higher F^- level in the groundwater. The linear regression results show that cation exchange occurred between Ca²⁺ and Na⁺ in deep groundwater, which could decrease the groundwater Ca²⁺ content and further promote the CaF₂ dissolution. There is good positive correlations between F^- and pH and $HCO 3 -$ in deep groundwater, indicating that the slightly alkaline environment and high $HCO 3 -$ content are beneficial to F^- desorption. In addition, there is strong positive F^- vs. Li correlation in deep groundwater, which also indicates that the local mixing of geothermal water may directly affect the F^- enrichment in deep groundwater. Comparing the hydrochemical and isotopic characteristics of deep groundwater with seawater, we found that the local F^- enrichment of deep groundwater is unaffected by seawater intrusion.

Key words: coastal plain, fluoride groundwater, distribution characteristic, water-rock interaction, Hebei Province

CLC Number:

P641.1

ZHANG Zhuo, CHEN Sheming, LIU Futian, GAO Zhipeng, NIU Xiaotong. Enrichment Mechanism of Deep Groundwater with High Fluoride in Coastal Plains: A Case Study of the Luanhe Delta[J]. Geoscience, 2023, 37(04): 925-932.

Figures/Tables 7

Fig.1 Distribution of groundwater sampling spots

Fig.2 Piper ternary diagrams(unit: %)

Fig.3 Bivariate plot of δD vs. δ18O

Fig.4 Plots of SIfluorite vs. SIcalcite(a)and activities of Ca2+ with F- concentrations((b), basemap after ref.[16])

Fig.5 Bivariate plot of Ca2++Mg2+- SO 4 2 -- HCO 3 - vs.Na++K+-Cl-

Fig.6 Relationships between groundwater F- and Na+/(Ca2+)0.5 (a), pH (b), HCO 3 - (c), and Li (d)

Fig.7 Bivariate plot of the Cl-/ HCO 3 - vs. Cl-

References 37

[1]	YADAV K K, KUMAR S, PHAM Q B, et al. Fluoride contamination, health problems and remediation methods in Asian groundwater: A comprehensive review[J]. Ecotoxicology and Environmental Safety, 2019, 182: 109362. DOI URL
[2]	MCMAHON P B, BROWN C J, JOHNSON T D, et al. Fluoride occurrence in United States groundwater[J]. Science of the Total Environment, 2020, 732: 139217. DOI URL
[3]	VIKAS C, KUSHWAHA R, AHMAD W, et al. Genesis and geochemistry of high fluoride bearing groundwater from a semi-arid-terrain of NW India[J]. Environmental Earth Sciences, 2013, 68(1): 289-305. DOI URL
[4]	DE SOUZA C F M, LIMA J F J, ADRIANO M S P F, et al. Assessment of groundwater quality in a region of endemic fluorosis in the northeast of Brazil[J]. Environmental Monitoring and Assessment, 2013, 185(6): 4735-4743. DOI PMID
[5]	RAFIQUE T, NASEEM S, USMANI T H, et al. Geochemical factors controlling the occurrence of high fluoride groundwater in the Nagar Parkar area, Sindh, Pakistan[J]. Journal of Hazar-dous Materials, 2009, 171(1/2/3): 424-430.
[6]	邢丽娜, 郭华明, 魏亮, 等. 华北平原浅层含氟地下水演化特点及成因[J]. 地球科学与环境学报, 2012, 34(4): 57-67.
[7]	冯海波, 董少刚, 史晓珑, 等. 内蒙古托克托县潜水与承压水中氟化物的空间分布特征及形成机理[J]. 现代地质, 2016, 30(3): 672-679.
[8]	苗晋杰, 靳继红, 杜东, 等. 首都副中心及重点区域地下水环境质量评价与问题成因[J]. 地质调查与研究, 2020, 43(3): 224-229, 286.
[9]	LI P Y, HE X D, LI Y, et al. Occurrence and health implication of fluoride in groundwater of loess aquifer in the Chinese Loess Plateau: A case study of Tongchuan, northwest China[J]. Exposure and Health, 2019, 11(2): 95-107. DOI
[10]	WANG Y X, LI J X, MA T, et al. Genesis of geogenic contaminated groundwater: As, F and I[J]. Critical Reviews in Environmental Science and Technology, 2021, 51(24): 2895-2933. DOI URL
[11]	2016年我国卫生和计划生育事业发展统计公报发布[J]. 健康管理, 2017(9): 22-30.
[12]	AYOOB S, GUPTA A K. Fluoride in drinking water: A review on the status and stress effects[J]. Critical Reviews in Environmental Science and Technology, 2006, 36(6): 433-487. DOI URL
[13]	SU C L, WANG Y X, XIE X J, et al. An isotope hydrochemical approach to understand fluoride release into groundwaters of the Datong Basin, Northern China[J]. Environmental Science(Processes and Impacts), 2015, 17(4): 791-801.
[14]	WANG Y X, SHVARTSEV S L, SU C L. Genesis of arsenic/fluoride-enriched soda water: A case study at Datong, Northern China[J]. Applied Geochemistry, 2009, 24(4): 641-649. DOI URL
[15]	王文祥, 何锦, 张梦南, 等. 张掖盆地龙首山山前高氟地下水的形成[J]. 现代地质, 2017, 31(2): 415-420.
[16]	LIU H Y, GUO H M, YANG L J, et al. Occurrence and formation of high fluoride groundwater in the Hengshui area of the North China Plain[J]. Environmental Earth Sciences, 2015, 74(3): 2329-2340. DOI URL
[17]	毛若愚, 郭华明, 贾永锋, 等. 内蒙古河套盆地含氟地下水分布特点及成因[J]. 地学前缘, 2016, 23(2): 260-268. DOI
[18]	GUO H M, ZHANG Y, XING L N, et al. Spatial variation in arsenic and fluoride concentrations of shallow groundwater from the town of Shahai in the Hetao Basin, Inner Mongolia[J]. Applied Geochemistry, 2012, 27(11): 2187-2196. DOI URL
[19]	李予红, 宋晓光, 胡斌, 等. 张家口坝上地区高氟地下水分布与成因分析[J]. 北京师范大学学报(自然科学版), 2021, 57(6): 745-755.
[20]	WEN D G, ZHANG F C, ZHANG E Y, et al. Arsenic, fluoride and iodine in groundwater of China[J]. Journal of Geochemical Exploration, 2013, 135: 1-21. DOI URL
[21]	WANG Z, GUO H M, XING S P, et al. Hydrogeochemical and geothermal controls on the formation of high fluoride groundwater[J]. Journal of Hydrology, 2021, 598: 126372. DOI URL
[22]	陈桥, 史文静, 芦清水, 等. 海水入侵对莱州湾地下水氟释放潜在影响研究[J]. 海洋科学进展, 2012, 30(2): 219-228.
[23]	CHEN Q, JIA C P, WEI J C, et al. Geochemical process of groundwater fluoride evolution along global coastal Plains: Evidence from the comparison in seawater intrusion area and soil salinization area[J]. Chemical Geology, 2020, 552: 119779. DOI URL
[24]	方成, 柳富田, 孟利山, 等. 氢氧同位素在曹妃甸地区水循环研究中的应用[J]. 地质调查与研究, 2014, 37(2): 102-107.
[25]	OZSVATH D L. Fluoride concentrations in a crystalline bedrock aquifer Marathon County, Wisconsin[J]. Environmental Geology, 2006, 50(1): 132-138. DOI URL
[26]	KIM S H, KIM K, KO K S, et al. Co-contamination of arsenic and fluoride in the groundwater of unconsolidated aquifers under reducing environments[J]. Chemosphere, 2012, 87(8): 851-856. DOI URL
[27]	PATEL S C, KHALKHO R, PATEL S K, et al. Fluoride contamination of groundwater in parts of eastern India and a preliminary experimental study of fluoride adsorption by natural hematite iron ore and synthetic magnetite[J]. Environmental Earth Sci-ences, 2014, 72(6): 2033-2049.
[28]	KUMAR M, DAS N, GOSWAMI R, et al. Coupling fractionation and batch desorption to understand arsenic and fluoride co-contamination in the aquifer system[J]. Chemosphere, 2016, 164: 657-667. DOI PMID
[29]	PI K F, WANG Y X, XIE X J, et al. Hydrogeochemistry of co-occurring geogenic arsenic, fluoride and iodine in groundwater at Datong Basin, Northern China[J]. Journal of Hazardous Materials, 2015, 300: 652-661. DOI PMID
[30]	GUO Q H, WANG Y X, MA T, et al. Geochemical processes controlling the elevated fluoride concentrations in groundwaters of the Taiyuan Basin, Northern China[J]. Journal of Geochemical Exploration, 2007, 93(1): 1-12. DOI URL
[31]	龚育龄. 中国东部渤海湾盆地热结构和热演化[D]. 南京: 南京大学, 2003.
[32]	董月霞, 黄红祥, 任路, 等. 渤海湾盆地北部新近系馆陶组地热田特征及开发实践: 以河北省唐山市曹妃甸地热供暖项目为例[J]. 石油勘探与开发, 2021, 48(3): 666-676. DOI
[33]	MAO X M, ZHU D B, NDIKUBWIMANA I, et al. The mechanism of high-salinity thermal groundwater in Xinzhou geothermal field, South China: Insight from water chemistry and stable isotopes[J]. Journal of Hydrology, 2021, 593: 125889. DOI URL
[34]	MAITY J P, LIU C C, NATH B, et al. Biogeochemical characteristics of Kuan-Tzu4 Ling, Chung-Lun and Bao-Lai hot springs in southern Taiwan: A possible sources of groundwater arsenic[J]. Journal of Environmental Science and Health, 2011, 46(11): 1207-1217.
[35]	李雪, 叶思源. 海水入侵调查方法研究进展[J]. 海洋地质与第四纪地质, 2016, 36(6): 211-217.
[36]	杨吉龙, 韩冬梅, 苏小四, 等. 环境同位素特征对滨海岩溶地区海水入侵过程的指示意义[J]. 地球科学进展, 2012, 27(12): 1344-1352. DOI
[37]	ZUO R, LIU X, YANG J, et al. Distribution, origin and key influencing factors of fluoride groundwater in the coastal area, NE China[J]. Human and Ecological Risk Assessment, 2019, 25(1/2): 104-119. DOI URL