Journal of Jilin University(Earth Science Edition) ›› 2016, Vol. 46 ›› Issue (3): 831-843.doi: 10.13278/j.cnki.jjuese.201603205

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Shallow Groundwater Hydrogeochemical Evolution Process and Controlling Factors in Plain Zone of Guanghan City

Chen Meng, Wu Yong, Gao Dongdong, Chang Ming   

  1. State Key Laboratory for Geo-Hazard Prevention and Geo-Environment Protection, Chengdu University of Technology, Chengdu 610059, China
  • Received:2015-10-03 Online:2016-05-26 Published:2016-05-26
  • Supported by:

    Supported by State Key Laboratory for Geohazard Prevention and Geoenvironment Protection Project (SKLGP2009Z006) and Key Technology R & D Program of Science and Technology Department of Sichuan Province(2011SZ0172)

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Abstract:

Four methods, including mineral weathering system analysis, correlation analysis, principal component analysis and inverse hydrogeochemical simulation by PhreeQC are used to analyse the chemical composition, identify hydrogeochemical evolution processes and controlling factors, then complete analyzing quality and spatial temporal distribution of shallow groundwater in the plain of Guanghan City, which provides basic data for developing and utilizing groundwater resources exsisting in urban and rural planning process. The analysis showes that Gibbs plots indicate that the groundwater hydrochemical characteristics are dominated by rock weathering, the weathering processes produce ions and then secondary minerals undergo hydrolysis; aluminosilicate minerals of water samples tend to dissolve gradually in the mineral weathering system stability diagram; carbonate minerals are saturated. PhreeQC inverse hydrogeochemical simulation results show what mainly happen in the water flow path simulation are the dissolution of calcium montmorillonite and K-feldspar, the precipitation of kaolinite, quartz and albite, and the cation exchange adsorption between Ca-Na2; The analysis of ion correlation and principal component analysis verifies that leaching, evaporation and concentrating, and cation exchange adsorption are the main cause of hydrochemical process and mineral composition in the shallow groundwater. The groundwater quality in the study area generally will not cause adverse effects on human health.

Key words: Guanghan City, hydrogeochemical evolution, water-rock interaction, principal component analysis, inverse hydrogeochemical simulation, groundwater quality

CLC Number: 

  • P641.3

[1] Morris B L, Lawrence A R L, Chilton P J C,et al.Groundwater and Its Susceptibility to Degradation:A Global Assessment of the Problem and Options forManagement[C]//Early Warning and Assessment Report Series, RS.Nairobi:United Nations Environment Programme.2003:3-6.

[2] 李义连, 王焰新, 周来茹, 等. 地下水矿物饱和度的水文地球化学模拟分析:以娘子关泉域岩溶水为例[J]. 地质科技情报, 2002, 21(1):32-36. Li Yilian, Wang Yanxin, Zhou Lairu, et al. Hydrogeochemical Modeling on Saturation of Minerals in Groundwater:A Case Study at Niangziguan, Northern China[J]. Geological Science and Technology Information, 2002, 21(1):32-36.

[3] GB/T 5750-2006生活饮用水标准检验法[S].北京:中国标准出版社, 2007. GB/T 5750-2006 Standard Examination Methods for Drinking Water[S]. Beijing:China Standard Publishing, 2007.

[4] Todd D K.Groundwater Hydrology[M].2nd ed. New York:Wiley, 1980.

[5] 唐启义. DPS数据处理系统:实验设计、统计分析及数据挖掘[M]. 三版.北京:科学出版社, 2010. Tang Qiyi. Data Processing System:Experimental Design, Statistical Analysis and Data Mining[M].3rd ed. Beijing:Science Press,2010.

[6] Cloutier V, Lefebvre R, Therrien R, et al. Multivariate Statistical Analysis of Geochemical Data as Indicative of the Hydrogeochemical Evolution of Groundwater in a Sedimentary Rock Aquifer System[J]. J Hydrol,2008, 353:294-313.

[7] Kamtchueng B T, Fantong W Y, Ueda A, et al. Assess-ment of Shallow Groundwater in Lake Nyos Catchment (Cameroon, Central-Africa):Implications for Hydrogeochemical Controls and Uses[J]. Environ Earth Sci,2014, 72:3663-3678.

[8] Baeza C, Corominas J. Assessment of Shallow Landslide Susceptibility by Means of Multivariate Statistical Techniques[J]. Earth Surf Process Landforms,2001, 26(12):1251-1263.

[9] Koklu R, Sengorur B, Topal B. Water Quality Assessment Using Multivariate Statistical Methods:A Case Study:Melen River System (Turkey)[J]. Water Resour Manage, 2010, 24:959-978.

[10] Yidana S M, Banoeng-Yakubo B, Akabzaa T M. Analysis of Groundwater Quality Using Multivariate and Spatial Analyses in the Keta Basin, Ghana[J]. J Afr Earth Sci,2010, 58:220-234.

[11] Carroll S,Goonetilleke A. Assessment of High Density of Onsite Wastewater Treatment Systems on a Shallow Groundwater Coastal Aquifer Using PCA[J]. Environmetrics, 2005, 16:257-274.

[12] Koonce J E, Yu Z, Farnham I M, et al. Geochemical Interpretation of Groundwater Flow in the Southern Great Basin[J]. Geosphere, 2006, 2:88-101.

[13] Wu J H, Li P Y, Qian H.Using Correlation and Mul-tivariate Statistical Analysisto Identify Hydrogeochemical Processes Affecting the Major Ion Chemistry of Waters:A Case Study in Laoheba Phosphorite Minein Sichuan, China[J]. Arab J Geosci, 2014, 7:3973-3982.

[14] 冯利华, 马未宇.主成分分析法在地区综合实力评价中的应用[J].地理与地理信息科学, 2004, 20(6):73-75. Feng Lihua,Ma Weiyu. Application of Principal Component Analysis in Evaluation of Area's Comprehensive Strength[J].Geography and Geo-Information Science, 2004, 20(6):73-75.

[15] 刘丽红,束龙仓,王茂枚, 等. 主成分分析法识别岩溶多重介质含水系统水化学和水动力特性:以贵州后寨岩溶典型小流域为例[J].工程勘察, 2009, (6):43-47. Liu Lihong, Shu Longcang, Wang Maomei, et al.Application of Principal Component Analysis to Identify the Hydrodynamic and Hydrochemistry Characteristics in Karst Multimedia System:A Case Study on the Karst in Houzhai of Guizhou[J]. Geotechnical Investigation & Surveying,2009, (6):43-47.

[16] Piper A M. A Graphic Procedure in the Geochemical Interpretation of Water Analysis[R].Washington D C:United States Geological Survey,1953.

[17] Gibbs R J. Mechanisms Controlling World Water Chemi-stry[J].Science, 1970, 17:1088-1090.

[18] 梁云甫. 成都平原更新世黏土类土的工程地质特征[J]. 勘察科学技术, 1987, (6):43-46. Liang Yunfu.The Engineering Geological Characteristics of Chengdu Plain Pleistocene Clay Soil[J]. Site Investigation Science and Technology, 1987, (6):43-46.

[19] 汪波,聂前勇,王运生,等. 也论成都黏土的成因[J]. 地质灾害与环境保护, 2002, 13(1):54-57,64. Wang Bo,Nie Qianyong, Wang Yunsheng, et al.Discussionon the Genetic Mechanism of Chengdu Clay[J]. Journal of Geological Hazards and Environment Preservation, 2002, 13(1):54-57,64.

[20] 邵之刚, 李代钧, 李永昭.成都平原更新世黏土的地质特征[C]//中国地质学会第四纪冰川与第四纪地质专业委员会, 江苏省地质学会.第四纪冰川与第四纪地质论文集:一.北京:地质出版社, 1984:142-152. Shao Zhigang, Li Daijun, Li Yongzhao. Geological Characteristics of Pleistocene Clay in the Chengdu Plain[C]//Commission on Quaternary Glaciology and Geology of the Geological Society of China, Geological Society of Jiangsu Province.Contribution to the Quaternary Glaciology and Quaternary Geology:1. Beijing:Geological Publishing House, 1984:142-152.

[21] Appelo C A J, Postma D. Chemical Analysis of Ground-water,Geochemistry, Groundwater and Pollution[M].2nd ed. Balkema:Rotterdam, 2005.

[22] 高东东, 吴勇, 王春红. 彭州通济地区水文地球化学特征及成因分析[J]. 地下水, 2010, 32(6):49-53,132. Gao Dongdong, Wu Yong, Wang Chunhong.Hydro-Geochemical Characteristics and Formation Reason of Shallow Ground Water in Tongji Area of Pengzhou[J]. Ground Water, 2010, 32(6):49-53,132.

[23] Tardy Y. Characterization of the Principal Weathering Types by the Geochemistry of Waters from some European and African Crystalline Massifs[J]. Chem Geol,1971, 7:253-271.

[24] 沈照理.水文地球化学基础[M].北京:地质出版社, 1993. Shen Zhaoli. Basic of Hydrogeochemistry[M].Beijing:Geological Publishing House, 1993.

[25] 姜光辉, 郭芳,于奭.岩溶水系统的水化学曲线及其在水文地质研究中的应用[J]. 吉林大学学报(地球科学版), 2015,45(3):899-907. Jiang Guanghui, Guo Fang, Yu Shi. Chemographs of Karst Water System and Its New Application in Hydrogeological Survey[J]. Journal of Jinlin University(Earth Science Edition), 2015,45(3):899-907.

[26] Bouwer H. Integrated Water Management:Emerging Issues and Challenges[J]. Agricultural Water Management,2000,45:217-228.

[27] WHO. Guidelines for Drinking Water Quality[M].4th ed. WHO, 2011.

[28] GB 5749-2006生活饮用水卫生标准[S].北京:中国标准出版社, 2007. GB 5749-2006 Standard for Drinking Water Quality[S]. Beijing:China Standard Publishing, 2007.

[29] Ong C N, Grandjean A C, Heaney R P. The Mineral Composition of Water and Its Contribution to Calcium and Magnesium Intake[C]//Calcium and Magnesium in Drinking-Water Public Health Significance. Geneva:WHO, 2009:36-58.

[30] 李明辉, 王剑, 王建祥. 锅炉给水中氯离子危害浅析[J]. 装备制造技术, 2012(9):240-241. Li Minghui, Wang Jian, Wang Jianxiang. Research of Disadvantage on ChlorideIon in Boiler Feed-Water[J]. Equipment Manufactring Technology, 2012(9):240-241.

[31] 胡玉福, 邓良基, 张世熔,等. 四川盆地西缘浅层地下水铁、锰含量的空间变异特征[J]. 生态学报, 2009, 29(2):797-803. Hu Yufu,Deng Liangji,Zhang Shirong, et al. Spatial Variability of Iron and Manganese Contents in Shallow Groundwater in the West of Sichuan Basin[J]. CtaEcologica Sinica, 2009, 29(2):797-803.
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