Establishment of the relationship between contamination concentration and electrical resistivity in shallow aquifer based on groundwater numerical modeling

doi:10.7523/j.issn.2095-6134.2018.06.013

Abstract

Abstract: Geophysical method is an important technique in groundwater contamination investigation. The geoelectrical method is capable of mapping both low and high resistivity and has been commonly used to explore concentration of contamination in groundwater. How to convert apparent resistivity of groundwater into concentration distribution of contamination in groundwater should be first considered carefully. Therefore, it is necessary to establish a relationship between electrical resistivity and contamination concentration for concentration estimation using geoelectrical information. We present a method for establishing this relationship based on groundwater numerical model. In this method, the relationship of electrical information and concentration information is obtained by comparing the contamination data from solute transport model with the electrical resistivity data from geophysical forward and inverse modeling. The results show that there is a clear relationship between the electrical resistivity and contamination concentration, which also has a spatial heterogeneity. The applications of the relationships established using linear fitting and polynomial fitting both are better than that by converting electrical resistivity data to concentration directly using Archie's law. In addition, the relationship established using polynomial fitting is better than that using linear fitting in some cases. The method proposed in this work has great potential for estimating the concentration of groundwater concentration based on geoeletrical data.

Key words: groundwater contamination, concentration, electrical resistivity, groundwater numerical simulation

CLC Number:

P631.325

ZHAO Shaohua, DONG Yanhui, LI Xuelan, WANG Liheng. Establishment of the relationship between contamination concentration and electrical resistivity in shallow aquifer based on groundwater numerical modeling[J]. , 2018, 35(6): 814-821.

References

[1] 熊玲,鄢贵权. 浅谈我国地下水的污染现状及防治措施[J]. 贵州科学,2009,27(4):86-90.
[2] 郭永海, 王志明, 刘淑芬,等. 石家庄市地下水污染特征及其与超量开采的关系[J]. 铀矿地质, 2005, 21(2):123-127.
[3] 王爱平, 杨建青, 杨桂莲,等. 我国地下水监测现状分析与展望[J]. 水文, 2010, 30(6):53-56.
[4] 钟秋. 地下水污染调查中的地球物理方法[J]. 地下水, 2014, 36(2):57-58.
[5] 喻永祥, 吴吉春. 利用ERT数据推求非均质多孔介质渗透系数初探[J]. 水文地质工程地质, 2006, 33(2):41-44.
[6] 闫永利, 马晓冰, 袁国平,等. 大地电磁法在阿苏卫填埋场地下水污染检测的应用研究[J]. 地球物理学报, 2007, 50(6):1863-1868.
[7] 杨学明, 苏永军, 杜东,等. 音频大地电磁法在海水入侵动态监测中的应用[J]. 物探与化探, 2013, 37(2):301-305.
[8] Singha K, Moysey S. Accounting for spatially variable resolution in electrical resistivity tomography through field-scale rock-physics relations[J]. Geophysics, 2006, 71(4):A25.
[9] Singha K, Gorelick S M. Hydrogeophysical tracking of three-dimensional tracer migration:the concept and application of apparent petrophysical relations[J]. Water Resources Research, 2006, 42(6):253-263.
[10] Koestel J, Kemna A, Javaux M, et al. Quantitative imaging of solute transport in an unsaturated and undisturbed soil monolith with 3-D ERT and TDR[J]. Water Resources Research, 2008, 44(12):1-17.
[11] Pollock D, Cirpka O A. Temporal moments in geoelectrical monitoring of salt tracer experiments[J]. Water Resources Research, 2008, 44(12):723-729.
[12] Wehrer M, Slater L D. Characterization of water content dynamics and tracer breakthrough by 3-D electrical resistivity tomography (ERT) under transient unsaturated conditions[J]. Water Resources Research, 2015, 51(1):97-124.
[13] 李国山, 周启友, 刘汉乐,等. 高密度电阻率成像法监测静水中溶质运移过程[J]. 工程勘察, 2008(10):72-75.
[14] 张嘉, 王明玉. 非均质渗透介质纵向弥散度数值模拟估算法适宜性探析[J]. 中国科学院研究生院学报, 2011, 28(1):35-42.
[15] 薛禹群. 地下水数值模拟[M]. 北京:科学出版社, 2007.
[16] Harbaugh A W. MODFLOW-2005, the US Geological survey modular ground-water model:the ground-water flow process[M]. Reston:US Department of the Interior, US Geological Survey, 2005.
[17] Ma R, Zheng C M. Effects of density and viscosity in modeling heat as a groundwater tracer[J]. Groundwater, 2010, 48(3):380-389.
[18] 施庆国. 高密度电阻率法二维和三维有限差分正演计算[D]. 长春:吉林大学, 2012.