Abstract
Widespread definition of a groundwater system in three dimensions is necessary for the management and maintenance of groundwater resources. A magnetotelluric (MT) survey can be an effective geophysical prospecting method for imaging regional geological structures by measuring both shallow and deep resistivity. To demonstrate the capability of an MT survey to characterize a groundwater system, the Kumamoto area of central Kyushu in southwestern Japan was selected as a case study site because of its rich groundwater resources. Three-dimensional (3D) MT resistivity structure to a depth of 5 km was modeled by 1D inversion analysis of raw MT data and 3D interpolation of the resultant resistivity column data by the optimization principle method. Consequently, both deep and shallow aquifers were detected. A high-resistivity zone appears at depths between 500 and 2,000 m between the Futagawa–Hinagu faults and the Usuki–Yatsushiro tectonic line, which supports the existence of an aquiclude under the aquifer. The most important characteristic inferred from the 3D resistivity model is that the deep groundwater system below a depth of 1,000 m has two main flow paths. One path is likely to be through porous rocks because the low resistivity zone is regarded as tuff with sand and gravel, and the other flow path is interpreted to be through fractured zones along the Hinagu faults. Hence, the path and direction of the groundwater flows are probably controlled by geologic structures and the configuration of the active faults. These findings support the effectiveness of the MT method for investigating groundwater systems.
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References
Aarts, E. H. L., & Korst, J. H. M. (1990). Simulated annealing and Boltzmann machines. New York: Wiley.
Asaue, H., Koike, K., Yoshinaga, T., & Takakura, S. (2006). Magnetotelluric resistivity modeling for 3D characterizing the geothermal reservoir in the western side of Mt. Aso, SW Japan. Journal of Applied Geophysics, 58, 296–312.
Backus, G., & Gilbert, F. (1967). The resolving power of gross earth data. Geophysical Journal of the Royal Astronomical Society, 13, 247–276.
Becken, M., Ritter, O., Park, S. K., Bedrosian, P. A., Weckmann, U., & Weber, M. (2008). A deep crustal fluid channel into the San Andreas Fault System near Parkfield, California. Geophysical Journal International, 173, 718–732.
Chilès, J.-P., & Delfiner, P. (1999). Geostatistics: Modeling spatial uncertainty. New York: Wiley.
Gamble, T. D., Goubau, W. M., & Clarke, J. (1979). Magnetotelluric with a remote magnetic reference. Geophys, 44, 53–68.
Imai, I., Teraoka, Y., Ono, K., Matsui, K., & Okumura, K. (1980). 1:500,000 geological seat map of Japan. Kagoshima: Geological Survey of Japan.
Koike, K., & Matsuda, S. (2005). Spatial modeling of discontinuous geologic attributes with geotechnical applications. Engineering Geology, 78, 143–161.
Koike, K., Minta, T., Ishizaka, S., & Ohmi, M. (1996). Hydrogeological and ground-water resource analysis using a geotechnical database. Nonrenewable Resources, 5, 23–32.
Koike, K., Sakamoto, H., & Ohmi, M. (2001). Detection and hydrologic modeling of aquifers in unconsolidated alluvial plains through combination of borehole data sets: A case study of the Arao area, southwest Japan. Engineering Geology, 62, 301–317.
Koike, K., Shiraishi, Y., Verdeja, E., & Fujimura, K. (1998). Three-dimensional interpolation and lithofacies analysis of granular composition data for earthquake-engineering characterization of shallow soil. Mathematical Geology, 30, 733–759.
Matsuda, T. (1975). Magnitude and recurrence interval of earthquakes from a fault. Journal of the Seismological Society of Japan, 28, 269–283.
Matsumoto, T. (1939). Geology of Mihune District, Kumamoto prefecture, Kyusyu (with special reference to the Cretaceous system). The Journal of the Geological Society of Japan, 46, 1–12. (in Japanese with English abstract).
Möller, P., Weise, S. M., Althaus, Q., Bach, W., Behr, H. J., Borchardt, R., et al. (1997). Paleofluids and recent fluids in the upper continental crust: Results from the German continental deep drilling program (KTB). Journal of Geophysical Research, 102(B8), 18,223–18,254.
Mrinal, K. S., Bimalendu, B. B., & Paul, L. S. (1993). Nonlinear inversion of resistivity sounding data. Geophys, 58, 59–74.
Ranganayaki, R. P. (1984). An Interpretive analysis of magnetotelluric data. Geophys, 49, 1730–1748.
Takakura, S., Takeda, M., & Matsuo, K. (1994). Effects of regional noise on magnetotellurics and their removal by far remote reference method. Butsuri Tansa (Geophysical Exploration), 47, 24–35. (in Japanese with English abstract).
Tanaka, N., & Hirayama, T. (1988). Groundwater basin at the west foot of Mt. Aso. Urban Kubota, 27, 46–51. (in Japanese).
Thomas, C. W. (1999). Relation of streams, lakes, and wetlands to groundwater flow systems. Hydrogeology Journal, 7, 28–45.
Tushaar, S., Aditi, D. R., Asad, S. Q., & Jinxia, W. (2003). Sustaining Asia’s groundwater boom: An overview of issues and evidence. Natural Resources Forum, 27, 130–141.
Uchida, T., & Ogawa, Y. (1993). Development of FORTRAN code for two-dimensional magnetotelluric inversion with smoothness constraint, Open-file Report. Geological Survey of Japan, 205.
Vozoff, K., Ed. (1986). Magnetotelluric method. Geophysics Reprint Series 5, Tulsa: SEG.
Acknowledgments
The authors wish to express sincere thanks to NEDO and Nittetsu Mining Consultants Co., Ltd. for providing the MT reference data obtained in the Ogiri area of Kagoshima Prefecture, Japan. Sincere thanks are extended to two anonymous reviewers for their valuable and constructive comments that helped improve the clarity of the manuscript.
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Asaue, H., Kubo, T., Yoshinaga, T. et al. Application of Magnetotelluric (MT) Resistivity to Imaging of Regional Three-Dimensional Geologic Structures and Groundwater Systems. Nat Resour Res 21, 383–393 (2012). https://doi.org/10.1007/s11053-012-9184-2
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DOI: https://doi.org/10.1007/s11053-012-9184-2