洛阳盆地浅层地下水化学特征及其演化特征分析
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摘要
在系统采集并分析洛阳盆地浅层地下水样品的基础上,综合描述性统计、相关性分析、运用Piper三线图、Gibbs模型以及离子比例系数等方法,对洛阳盆地浅层地下水化学特征及其形成机理进行了分析和探讨。结果表明:HCO~-_3和Ca~(2+)分别是研究区浅层地下水中优势的阴、阳离子;HCO_3-Ca和HCO_3-Ca·Mg型为主要地下水化学类型;浅层地下水TDS和总硬度的平均浓度相对较低,平均值分别为450.5 mg/L和329.3 mg/L。本区浅层地下水化学特征的形成主要受到岩石风化作用的影响,地下水水质成分主要来自于碳酸盐岩和硅酸盐岩等矿物的长期风化溶解。同时,逆向阳离子交换作用也在一定程度上影响着浅层地下水化学的形成。
Multiple methods, including mathematical statistics, correlation matrices, Piper diagram, Gibbs mode and ionic ratios, were employed to analyze hydrochemical characteristics and formation mechanisms of the shadow groundwater in the Luoyang Basin on the basis of a systematic collection of water samples. The results show that HCO~-_3 and Ca~(2+) are the predominant anion and cation of shallow groundwater. The main hydrochemistry types of groundwater are HCO_3-Ca and HCO_3-Ca·Mg types. The concentration of total dissolved solids(TDS) and total hardness are relatively low in shallow groundwater, with averages of 450.5 mg/L and 329.3 mg/L, respectively. The chemical characteristics of shallow groundwater is mainly derived from the rock weathering. The main constituents of groundwater come from long-term weathering and dissolution of minerals such as carbonates and silicates. In addition, the reverse cation exchange also affects the formation process of shallow groundwater in a certain extent.
Multiple methods, including mathematical statistics, correlation matrices, Piper diagram, Gibbs mode and ionic ratios, were employed to analyze hydrochemical characteristics and formation mechanisms of the shadow groundwater in the Luoyang Basin on the basis of a systematic collection of water samples. The results show that HCO~-_3 and Ca~(2+) are the predominant anion and cation of shallow groundwater. The main hydrochemistry types of groundwater are HCO_3-Ca and HCO_3-Ca·Mg types. The concentration of total dissolved solids(TDS) and total hardness are relatively low in shallow groundwater, with averages of 450.5 mg/L and 329.3 mg/L, respectively. The chemical characteristics of shallow groundwater is mainly derived from the rock weathering. The main constituents of groundwater come from long-term weathering and dissolution of minerals such as carbonates and silicates. In addition, the reverse cation exchange also affects the formation process of shallow groundwater in a certain extent.
引文
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[13] 洪涛, 谢运球, 喻崎雯, 等. 乌蒙山重点地区地下水水化学特征及成因分析[J]. 地球与环境, 2016, 44(1):11-18.
[14] 田西昭, 单强, 宋利震. 唐山沿海地区地下水化学特征及演化趋势分析[J]. 南水北调与水利科技, 2011, 9(1): 139-144.
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[16] Lakshmanan E, Kannan R, Kumar M S. Major ion chemistry and identification of hydrogeochemical processes of ground water in a part of Kancheepuram district, Tamil Nadu, India[J]. Environmental Geosciences, 2003, 10(4): 157-166.
[2] 蒲焘, 何元庆, 朱国锋, 等. 丽江盆地地表-地下水的水化学特征及其控制因素[J]. 环境科学, 2012, 33(1): 48-54.
[3] 侯昭华, 徐海, 安芷生. 青海湖流域水化学主离子特征及控制因素初探[J]. 地球与环境, 2009, 37(1): 11-19.
[4] 陈峰, 杨利国, 龚晓凌. 洛阳盆地浅层地下水资源形势分析[J]. 地下水, 2007,29(4):89-90.
[5] 王现国, 彭涛. 洛阳市浅层孔隙地下水化学环境演化分析[J]. 人民黄河, 2009,31(4):58-60.
[6] 王现国, 梁龙豹, 冯劼东, 等. 洛阳盆地地下水人工调控试验研究[J]. 人民黄河, 2006,28(7): 67-68.
[7] 姜体胜, 杨忠山, 王明玉, 等. 北京市南口地区浅层地下水水化学时空变化特征分析[J]. 地球与环境, 2011, 39(2): 203-208.
[8] 王晓曦, 王文科, 王周锋, 等. 滦河下游河水及沿岸地下水水化学特征及其形成作用[J]. 水文地质工程地质, 2014,(1): 25-33.
[9] Amiel R B, Grodek T, Frumkin A. Characterization of the hydrogeology of the sacred Gihon spring, Jerusalem: A deteriorating urban karst spring[J]. Hydrogeology Journal, 2010, 18(6): 1465-1479.
[10] Gibbs R J. Mechanisms controlling world water chemistry[J]. Science, 1970, 170(3962): 1088-1090.
[11] 许文峰, 王现国, 刘记成, 等. 洛阳盆地地下水动力场环境演化研究[J]. 人民黄河,2007,29(2): 54-55.
[12] 章光新, 邓伟, 何岩, 等. 中国东北松嫩平原地下水水化学特征与演变规律[J]. 水科学进展, 2006, 17(1): 20-28.
[13] 洪涛, 谢运球, 喻崎雯, 等. 乌蒙山重点地区地下水水化学特征及成因分析[J]. 地球与环境, 2016, 44(1):11-18.
[14] 田西昭, 单强, 宋利震. 唐山沿海地区地下水化学特征及演化趋势分析[J]. 南水北调与水利科技, 2011, 9(1): 139-144.
[15] Chang J, Wang G. Major ions chemistry of groundwater in the arid region of Zhangye Basin, northwestern China[J]. Environmental Earth Sciences, 2010, 61(3): 539-547.
[16] Lakshmanan E, Kannan R, Kumar M S. Major ion chemistry and identification of hydrogeochemical processes of ground water in a part of Kancheepuram district, Tamil Nadu, India[J]. Environmental Geosciences, 2003, 10(4): 157-166.
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