參考文獻 |
Advanced Geosciences, I. (2004). Instruction Manual for EarthImager 2D, Version 2.1. 7, Resistivity and IP Inversion Software.
Advanced Geosciences, I. (2009). Instruction Manual for EarthImager 2D, Version 2.4. 0, Resistivity and IP Inversion Software.
AL-Hammedawi, M. M. (2019). Forward and Inversion in Resistivity Method. 16.
Angelier, J., Chu, H.-T., Lee, J.-C., & Hu, J.-C. (2000). Active faulting and earthquake hazard: The case study of the Chihshang fault, Taiwan. Journal of Geodynamics, 29(3-5), 151-185.
Barker, R. (1979). Signal contribution sections and their use in resistivity studies. Geophysical Journal International, 59(1), 123-129.
Barker, R. (1989). Depth of investigation of collinear symmetrical four-electrode arrays. Geophysics, 54(8), 1031-1037.
Beasley, C. W., & Ward, S. H. (1988). Cross-borehole resistivity inversion SEG Technical Program Expanded Abstracts 1988 (pp. 198-200): Society of Exploration Geophysicists.
Bing, Z., & Greenhalgh, S. (2000). Cross‐hole resistivity tomography using different electrode configurations. Geophysical prospecting, 48(5), 887-912.
Bing, Z., & Greenhalgh, S. A. (1997). A synthetic study on crosshole resistivity imaging using different electrode arrays. Exploration Geophysics, 28(1-2), 1-5.
Bing, Z., & Greenhalgh, S. A. (1998). Composite boundary-valued solution of the 2.5-D Green’s function for arbitrary acoustic media. Geophysics, 63(5), 1813-1823.
Bing, Z., & Greenhalgh, S. A. (1999). Explicit expressions and numerical calculations for the Fréchet and second derivatives in 2.5 D Helmholtz equation inversion. Geophysical prospecting, 47(4), 443-468.
Binley, A., Cassiani, G., Middleton, R., & Winship, P. (2002). Vadose zone flow model parameterisation using cross-borehole radar and resistivity imaging. Journal of Hydrology, 267(3-4), 147-159.
Bott, M. (1967). Solution of the linear inverse problem in magnetic interpretation with application to oceanic magnetic anomalies. Geophysical Journal International, 13(1-3), 313-323.
Carey, A. M., Paige, G. B., Carr, B. J., & Dogan, M. (2017). Forward modeling to investigate inversion artifacts resulting from time-lapse electrical resistivity tomography during rainfall simulations. Journal of Applied Geophysics, 145, 39-49.
Chang, P.-Y., Chen, C.-c., Chang, S.-K., Wang, T.-B., Wang, C.-Y., & Hsu, S.-K. (2012). An investigation into the debris flow induced by Typhoon Morakot in the Siaolin Area, Southern Taiwan, using the electrical resistivity imaging method. Geophysical Journal International, 188(3), 1012-1024.
Chang, P.-Y., Huang, W.-J., Chen, C.-C., Hsu, H.-l., Yen, I.-C., Ho, G.-R., et al. (2018). Probing the frontal deformation zone of the Chihshang Fault with boreholes and high-resolution electrical resistivity imaging methods: A case study at the Dapo site in eastern Taiwan. Journal of Applied Geophysics, 153, 127-135.
Chen, W.-S., Yen, I.-C., Fengler, K. P., Rubin, C. M., Yang, C.-C., Yang, H.-C., et al. (2007). Late Holocene paleoearthquake activity in the middle part of the Longitudinal Valley fault, eastern Taiwan. Earth and Planetary Science Letters, 264(3-4), 420-437.
Cheng, L.-W., Lee, J.-C., Hu, J.-C., & Chen, H.-Y. (2009). Coseismic and postseismic slip distribution of the 2003 Mw= 6.5 Chengkung earthquake in eastern Taiwan: Elastic modeling from inversion of GPS data. Tectonophysics, 466(3-4), 335-343.
Dahlin, T., & Loke, M. H. (1998). Resolution of 2D Wenner resistivity imaging as assessed by numerical modelling. Journal of Applied Geophysics, 38(4), 237-249.
Dahlin, T., & Zhou, B. (2001). A numerical comparison of 2D resistivity imaging with eight electrode arrays. Paper presented at the Proceedings of the 7th Meeting, Environmental and Engineering Geophysics.
Daily, W., & Owen, E. (1991). Cross-borehole resistivity tomography. Geophysics, 56(8), 1228-1235.
Daily, W., & Yorkey, T. J. (1988). Evaluation of cross-borehole resistivity tomography SEG Technical Program Expanded Abstracts 1988 (pp. 201-203): Society of Exploration Geophysicists.
Dey, A., & Morrison, H. F. (1979). Resistivity modeling for arbitrarily shaped three-dimensional structures. Geophysics, 44(4), 753-780.
Evjen, H. M. (1938). Depth factors and resolving power of electrical measurements. Geophysics, 3(2), 78-95.
Farquharson, C. G., & Oldenburg, D. W. (1998). Non-linear inversion using general measures of data misfit and model structure. Geophysical Journal International, 134(1), 213-227. doi:10.1046/j.1365-246x.1998.00555.x
Fikos, I., Vargemezis, G., Zlotnicki, J., Puertollano, J., Alanis, P., Pigtain, R., et al. (2012). Electrical resistivity tomography study of Taal volcano hydrothermal system, Philippines. Bulletin of Volcanology, 74(8), 1821-1831.
Friedel, S. (2003). Resolution, stability and efficiency of resistivity tomography estimated from a generalized inverse approach. Geophysical Journal International, 153(2), 305-316. doi:10.1046/j.1365-246X.2003.01890.x
Griffiths, D., & Barker, R. (1993). Two-dimensional resistivity imaging and modelling in areas of complex geology. Journal of Applied Geophysics, 29(3-4), 211-226.
Hermans, T., Vandenbohede, A., Lebbe, L., & Nguyen, F. (2012). A shallow geothermal experiment in a sandy aquifer monitored using electric resistivity tomography. Geophysics, 77(1), B11-B21.
Jupp, D., & Vozoff, K. (1975). Stable iterative methods for the inversion of geophysical data. Geophysical Journal International, 42(3), 957-976.
Kumar, D., Thiagarajan, S., & Rai, S. (2011). Deciphering geothermal resources in Deccan Trap region using electrical resistivity tomography technique. Journal of the Geological Society of India, 78(6), 541-548.
Lankston, R. W. (1989). The seismic refraction method: A viable tool for mapping shallow targets into the 1990s. Geophysics, 54(12), 1535-1542.
Lee, J.-C., Angelier, J., Chu, H.-T., Hu, J.-C., & Jeng, F.-S. (2001). Continuous monitoring of an active fault in a plate suture zone: a creepmeter study of the Chihshang Fault, eastern Taiwan. Tectonophysics, 333(1-2), 219-240.
Lee, J.-C., Angelier, J., Chu, H.-T., Hu, J.-C., & Jeng, F.-S. (2005). Monitoring active fault creep as a tool in seismic hazard mitigation. Insights from creepmeter study at Chihshang, Taiwan. Comptes Rendus Geoscience, 337(13), 1200-1207.
Lee, J.-C., Angelier, J., Chu, H. T., Hu, J. C., Jeng, F. S., & Rau, R. J. (2003). Active fault creep variations at Chihshang, Taiwan, revealed by creep meter monitoring, 1998–2001. Journal of Geophysical Research: Solid Earth, 108(B11).
Lehmann, P., Gambazzi, F., Suski, B., Baron, L., Askarinejad, A., Springman, S. M., et al. (2013). Evolution of soil wetting patterns preceding a hydrologically induced landslide inferred from electrical resistivity survey and point measurements of volumetric water content and pore water pressure. Water Resources Research, 49(12), 7992-8004.
Loke, M. (1994). The inversion of two-dimensional apparent resistivity data. unpubl. Ph. D. thesis, Un. of Birmingham (UK).
Loke, M., & Barker, R. (1995). Least-squares deconvolution of apparent resistivity pseudosections. Geophysics, 60(6), 1682-1690.
Loke, M. H., & Barker, R. (1996). Rapid least‐squares inversion of apparent resistivity pseudosections by a quasi‐Newton method 1. Geophysical prospecting, 44(1), 131-152.
Looms, M. C., Jensen, K. H., Binley, A., & Nielsen, L. (2008). Monitoring unsaturated flow and transport using cross-borehole geophysical methods. Vadose zone journal, 7(1), 227-237.
M.H.Loke. (2004). Tutorial : 2-D and 3-D electrical imaging surveys.
Martínez-Pagán, P., Cano, Á. F., da Silva, G. R. R., & Olivares, A. B. (2010). 2-D Electrical Resistivity Imaging to Assess Slurry Pond Subsoil Pollution in the Southeastern Region of Murcia, SpainElectrical Resistivity Imaging and Slurry Ponds. Journal of Environmental and Engineering Geophysics, 15(1), 29-47.
McGILLIVRAY, P. R., & Oldenburg, D. (1990). Methods for calculating Fréchet derivatives and sensitivities for the non-linear inverse problem: a comparative study. Geophysical prospecting, 38(5), 499-524.
Menke, W. (2018). Geophysical data analysis: Discrete inverse theory: Academic press.
Metwaly, M., & AlFouzan, F. (2013). Application of 2-D geoelectrical resistivity tomography for subsurface cavity detection in the eastern part of Saudi Arabia. Geoscience Frontiers, 4(4), 469-476.
Metwaly, M., Khalil, M. A., Al-Sayed, E.-S., & El-Kenawy, A. (2013). Tracing subsurface oil pollution leakage using 2D electrical resistivity tomography. Arabian Journal of Geosciences, 6(9), 3527-3533.
Mu, C.-H., Angelier, J., Lee, J.-C., Chu, H.-T., & Dong, J.-J. (2011). Structure and Holocene evolution of an active creeping thrust fault: The Chihshang fault at Chinyuan (Taiwan). Journal of Structural Geology, 33(4), 743-755.
Ni, S., Ding, X., Helmberger, D. V., & Gurnis, M. (1999). Low-velocity structure beneath Africa from forward modeling. Earth and Planetary Science Letters, 170(4), 497-507.
Nishizawa, A., Kaneda, K., Katagiri, Y., & Kasahara, J. (2007). Variation in crustal structure along the Kyushu-Palau Ridge at 15–21 N on the Philippine Sea plate based on seismic refraction profiles. Earth, planets and space, 59(6), e17-e20.
Rawlinson, N., & Urvoy, M. (2006). Simultaneous inversion of active and passive source datasets for 3‐D seismic structure with application to Tasmania. Geophysical Research Letters, 33(24).
Rotstein, Y., Combs, J., & Biehler, S. (1976). Gravity investigation in the southeastern Mojave Desert, California. Geological Society of America Bulletin, 87(7), 981-993.
Sasaki, Y. (1992). RESOLUTION OF RESISTIVITY TOMOGRAPHY INFERRED FROM NUMERICAL SIMULATION 1. Geophysical prospecting, 40(4), 453-463.
Silvester, P. P., & Ferrari, R. L. (1996). Finite elements for electrical engineers: Cambridge university press.
Sirhan, A., & Hamidi, M. (2013). Detection of soil and groundwater domestic pollution by the electrical resistivity method in the West Bank, Palestine. Near surface geophysics, 11(4), 371-380.
Slater, L., Binley, A., Daily, W., & Johnson, R. (2000). Cross-hole electrical imaging of a controlled saline tracer injection. Journal of Applied Geophysics, 44(2-3), 85-102.
Springman, S. M., Thielen, A., Kienzler, P., & Friedel, S. (2013). A long-term field study for the investigation of rainfall-induced landslides. Geotechnique, 63(14), 1177.
Tang, J. T., Zhang, J. F., Feng, B., Lin, J. Y., & Liu, C. S. (2007). Determination of Borders for Resistive Oil and Gas Reservoirs by Deviation Rate Using the Hole‐to‐surface Resistivity Method. Chinese Journal of Geophysics, 50(3), 790-795.
Wang, T.-P., Chen, C.-C., Tong, L.-T., Chang, P.-Y., Chen, Y.-C., Dong, T.-H., et al. (2015). Applying FDEM, ERT and GPR at a site with soil contamination: a case study. Journal of Applied Geophysics, 121, 21-30.
Ward, S. H., & Hohmann, G. W. (1988). Electromagnetic theory for geophysical applications Electromagnetic Methods in Applied Geophysics: Voume 1, Theory (pp. 130-311): Society of Exploration Geophysicists.
Wilkinson, P. B., Chambers, J. E., Lelliott, M., Wealthall, G. P., & Ogilvy, R. D. (2008). Extreme sensitivity of crosshole electrical resistivity tomography measurements to geometric errors. Geophysical Journal International, 173(1), 49-62. doi:10.1111/j.1365-246X.2008.03725.x
Yi, M.-J., Kim, J.-H., & Son, J.-S. (2011). Three-dimensional anisotropic inversion of resistivity tomography data in an abandoned mine area. Exploration Geophysics, 42(1), 7-17.
Yu, S.-B., & Kuo, L.-C. (2001). Present-day crustal motion along the Longitudinal Valley Fault, eastern Taiwan. Tectonophysics, 333(1-2), 199-217.
Zhang, G., Zhang, G.-B., Chen, C.-C., & Jia, Z.-Y. (2015). Research on Inversion Resolution for ERT Data and Applications for Mineral Exploration. Terrestrial, Atmospheric & Oceanic Sciences, 26(5).
Zhou, B., & Dahlin, T. (2003). Properties and effects of measurement errors on 2D resistivity imaging surveying. Near surface geophysics, 1(3), 105-117.
王子賓. (2016). 交互應用各式地球物理探勘方法於土壤及地下水污染場址之研究. (博士論文), 國立中央大學地球科學學系.
江凱勝. (2017). 運用地電阻方法探測台中盆地主要水文地質架構. (碩士論文), National Central University.
吳秉昀. (2017). 地電阻影像法於海岸生物礁調查之研究 -以桃園觀音區為例 (碩士論文), 國立中央大學地球科學學系.
姚馨如. (2018). 應用二維地電阻法推估名竹盆地淺層含水層水位變化及比出水率. (碩士論文), National Central University.
姜彥麟, 朱傚祖, 李建成, & 黃志遠. (2012). 臺灣東部池上斷層全段之地表破裂與變形帶調查及構造特性分析. 經濟部中央地質調查所特刊, 第廿六號.
張竝瑜, 陳文山, 黃文正, & 郭陳浩. (2015). 重要活動斷層構造特性調查二期─活動斷層近地表構造特性調查(1/4)(計畫編號104-5226904000-0701). Retrieved from 經濟部中央地質調查所:
張竝瑜, 陳文山, 黃文正, & 郭陳浩. (2016). 重要活動斷層構造特性調查二期─活動斷層近地表構造特性調查(2/4)(計畫編號105-5226904000-0501). Retrieved from 經濟部中央地質調查所:
張竝瑜, 陳文山, 黃文正, & 郭陳浩. (2017). 重要活動斷層構造特性調查二期─活動斷層近地表構造特性調查(3/4)(計畫編號:106-5226904000-02-01). Retrieved from 經濟部中央地質調查所:
張竝瑜, 陳文山, 黃文正, & 郭陳浩. (2018). 重要活動斷層構造特性調查二期─活動斷層近地表構造特性調查(4/4)(計畫編號:107-5226904000). Retrieved from 經濟部中央地質調查所:
梅興泰, 鄭富書, & 蔡道賜. (2006). 地電阻影像剖面對非均質地下實體模擬的修正與分析. 技術學刊 (Journal of Technology), 21(4), 14.
郭治平, 劉興昌, 楊乃叡, & 林東暉. (2015). 以跨孔式地電阻檢測高壓噴射改良樁之應用助(編號 : MOST 104-2622-E-159-005-CC3). Professional Geotechnical Engineers(14), 3.
陳文山, & 王源. (1996). 臺灣東部海岸山脈地質: 經濟部中央地貭調查所.
馮正一, 陳奕凱, & 鄭旭涵. (2010). 應用 ERT 法於崩塌地特性調查與水分變化之研究. Jour nal of Chinese Soil and Water Conservation, 41 ((1)), 12.
蔡道賜, 黃富郎, & 柯瑞祥. (2014). 跨孔式 地電阻法於深埋管探查之應用. 中國土木水利工程學會, 41(5), 4.
|