Two-Dimensional Dipon Forward Modeling of High-Power Induced Polarization Mid-Stair Geological Exploration
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Author(s)
Wang Liang, Zhang Shaodong, Lv Zhibin, Zhu Jiejun
Corresponding Author
Wang Liang
Abstract
Among the geophysical exploration methods, conventional magnetotelluric methods have extensive and in-depth applications in many fields such as deep crustal structure and petroleum exploration. In this paper, by using the Cole-Cole model to introduce the complex resistivity into the Maxwell equation, the feasibility of extracting the four parameters of the Cole-Cole model from the observation data is explored, and finally the programming realizes the magnetotelluric two-dimensional tilter positive performance research. The staggered grid finite difference method is used for forward modeling, the conductivity in Maxwell equation is replaced with complex conductivity through Cole-Cole model, and Maxwell equation is discretized based on staggered sampling grid division and combined with boundary conditions to obtain the electric field value satisfied Linear equations. This paper analyzes the influence of the parameters of the Cole-Cole model on the polarizer through the forward simulation of two polarizers in a uniform half-space. The forward modeling results of the model show that the existence of the IP effect will increase the apparent resistivity value, and different IP parameters have different effects on the apparent resistivity. Among them, the polarizability has the greatest influence on the apparent resistivity; the greater the polarizability is , the greater the apparent resistivity.
Keywords
Induced polarization(ip) effect, Two-dimensional magnetotelluric, Cole-cole model, Data space
Acknowledgments
None
References
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