激发极化
地质学
反演(地质)
地下水
电阻率和电导率
地球物理学
含水层
土壤科学
矿物学
地貌学
岩土工程
物理
量子力学
构造盆地
作者
Xuben Wang,Juntao Lu,Ming Guo,Saimin Zhang,Qinglong Hu,Hesham El‐Kaliouby
出处
期刊:Geophysics
[Society of Exploration Geophysicists]
日期:2024-09-12
卷期号:: 1-46
被引量:2
标识
DOI:10.1190/geo2024-0010.1
摘要
Recent advancements in the signal-to-noise ratio of transient electromagnetic (TEM) devices have highlighted the significance of induced polarization (IP) effects in areas containing polarizable materials such as clays or sulfide minerals. These effects are characterized by an abnormally rapid decay followed by late-time negative values in the voltage response, which often lead to unsatisfactory outcomes in conventional resistivity-only inversion workflows. Previous research demonstrated that incorporating the Cole-Cole complex resistivity model into an inversion workflow enhances the characterization of this phenomenon. In a recent hydrological survey in eastern Tibet, China, significant TEM-IP-affected phenomena were observed during the implementation of an electrical-source TEM system to map the distribution of groundwater. In this instance, data from two representative survey lines were inverted using a modified quasi-two-dimensional (2D) regularized Newton inversion scheme, which simultaneously extracted the DC resistivity and three IP parameters: chargeability, time constant, and frequency dependence. The results revealed clear conductive polarization distributions against the resistive host, correlating well with groundwater-enriched weathered layers, as confirmed by borehole lithological logs. Consequently, conductive polarization signatures were identified as potential key indicators of groundwater presence considering potential associations with clay and shale. This case study emphasizes the significance of accounting for potential IP effects in TEM surveys and highlights the advantages of multiparametric inversion for achieving more accurate results and enhancing the interpretation of subsurface properties.
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