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Coal Geology & Exploration

Abstract

In the borehole transient electromagnetic method (TEM), the receiving probe is placed in the borehole, which is different from either aerial or ground TEM. In such methods, as the probe will be closer to the detection target and far away from surface, not only stronger response signals can be observed, but also the interference of various electromagnetic signals outside the borehole can be attenuated effectively. It can meet the demand of meticulous detection with large burial, especially the detection demand of deep blind ore and water hazard. The present situation of using various methods in the study in forward modeling, inversion imaging, instrument and equipment as well as application cases was summarized, by reviewing the study history of various borehole TEMs (return line source surface-to-borehole TEM, electric source surface-to-borehole TEM, and tunnel borehole TEM). According to the study results, the study of the return line source surface-to-borehole TEM, with solid foundation and comprehensive development, has been applied frequently and successfully in production. Both the study of electric source surface-to-borehole TEM and that of the tunnel borehole TEM have not been widely promoted or applied currently due to their weak foundation and the limitations in terms of theoretical methods, detection equipment, inversion techniques, etc. The study of the both TEMs is still at the preliminary stage, and the related technologies still require further improvement. For the future development direction, the implementation can be commenced in terms including the three-dimension (3D) inversion with topography, rapid topographic correction, pseudo-random emission, emission with multiple radiation sources, interference elimination for casings and the combined interpretation using the multi-parameter geophysical method, so as to form the complete borehole TEM theory and interpretation method, and to provide theoretical basis for the detection of deep ores and the detection of the water-bearing structures in coal and tunnels.

Keywords

surface-to-borehole TEM, tunnel borehole TEM, forward modeling and inversion, instrument and equipment, application cases

DOI

10.12363/issn.1001-1986.22.03.0182

Reference

[1] DYCK A V. Drill–hole electromagnetic methods[J]. Electromagnetic Methods in Applied Geophysics,1991,2:881−930.

[2] 牛之琏. 时间域电磁法原理[M]. 长沙:中南大学出版社,2007.

[3] 范涛. 孔巷瞬变电磁动源定接收方法探测采空区试验[J]. 煤炭学报,2017,42(12):3229−3238. FAN Tao. Experimental study on the exploration of coal mine goaf by dynamic source and fixed reception roadway–borehole TEM detection method[J]. Journal of China Coal Society,2017,42(12):3229−3238.

[4] IRVINE R J. Drillhole TEM surveys at Thalanga, Queensland[J]. Exploration Geophysics,1987,18:285−293.

[5] NEWMAN G A,ANDERSON W L,HOHMANN G W. Effect of conductive host rock on borehole transient electromagnetic responses[J]. Geophysics,1989,54(5):598−608.

[6] 吕庆田,张晓培,汤井田,等. 金属矿地球物理勘探技术与设备: 回顾与进展[J]. 地球物理学报,2019,62(10):3629−3664. LYU Qingtian,ZHANG Xiaopei,TANG Jingtian,et al. Review on advancement in technology and equipment of geophysical exploration for metallic deposits in China[J]. Chinese Journal of Geophysics,2019,62(10):3629−3664.

[7] 刘光鼎. 推动地球物理方法创新,引领探测仪器技术未来[J]. 地球物理学报,2017,60(11):4145−4148. LIU Guangding. Promote the innovation of geophysical methodology, and lead the future of exploration apparatus technology[J]. Chinese Journal of Geophysics,2017,60(11):4145−4148.

[8] ZHANG Z,XIAO J. Inversions of surface and borehole data from large–loop transient electromagnetic system over a 1–D earth[J]. Geophysics,2001,66(4):1090−1096.

[9] WOODS V D. A model study of the Crone borehole pulse electromagnetic (PEM) system[D]. Ontario:Queen’s University,1975.

[10] DYCK A V,WEST G F. The role of simple computer models in interpretations of wide–band,drill–hole electromagnetic surveys in mineral exploration[J]. Geophysics,1984,49(7):957−980.

[11] 武军杰,刘彬,智庆全,等. 井−地瞬变电磁联合探测在2 000 m深部找矿中的应用[J/OL]. 煤田地质与勘探,2022. https://kns.cnki.net/kcms/detail/61.1155.P.20220426.2110.002.html.

WU Junjie,LIU Bin,ZHI Qingquan,et al. Application of joint exploration with surface and borehole TEM in 2000m deep mineral exploration in the Baiyun gold deposit,Eastern Liaoning[J/OL]. Coal Geology & Exploration,2022. https://kns.cnki.net/kcms/detail/61.1155.P.20220426.2110.002.html.

[12] 蒋慎君,陈卫. 井中脉冲瞬变电磁法在苏皖地区寻找深部隐伏金属矿床中的应用效果[J]. 江苏地质,1987(2):46−52. JIANG Shenjun,CHEN Wei. The application of transient electromagnetic for deep concealed metallic deposits in the region of Jiangsu and Anhui[J]. Jiangsu Geology,1987(2):46−52.

[13] WEST R C,WARD S H. The borehole transient electromagnetic response of a three–dimensional fracture zone in a conductive half–space[J]. Geophysics,1988,53(11):1469−1478.

[14] 周仕新,岳建华. 巷道围岩中瞬变电磁场三维数值模拟[J]. 物探与化探,2005,29(6):533−536. ZHOU Shixin,YUE Jianhua. Numerical three–dimensional simulation of transient electromagnetic field in roadway and its surrounding rocks[J]. Geophysical & Geochemical Exploration,2005,29(6):533−536.

[15] 孟庆鑫,潘和平. 地–井瞬变电磁响应特征数值模拟分析[J]. 地球物理学报,2012,55(3):1046−1053. MENG Qingxin,PAN Heping. Numerical simulation analysis of surface–hole TEM responses[J]. Chinese Journal of Geophysics,2012,55(3):1046−1053.

[16] 徐正玉,杨海燕,邓居智,等. 回线源三维地–井瞬变电磁法FDTD数值模拟[J]. 工程地球物理学报,2015,12(3):327−332. XU Zhengyu,YANG Haiyan,DENG Juzhi,et al. 3 dimensions FDTD numerical simulation on the down–hole TEM filed with a loop source[J]. Chinese Journal of Engineering Geophysics,2015,12(3):327−332.

[17] 郭建磊,姜涛,郭恒,等. 轴向各向异性地–井瞬变电磁三分量响应特征[J]. 地球科学与环境学报,2020,42(6):737−748. GUO Jianlei,JIANG Tao,GUO Heng,et al. Characteristics of axial anisotropic borehole transient electromagnetic three–component response[J]. Journal of Earth Sciences and Environment,2020,42(6):737−748.

[18] EATON P A,HOHMANN G W. The influence of a conductive host on two–dimensional borehole transient electromagnetic responses[J]. Geophysics,1984,49(7):861−869.

[19] BUSELLI G,LEE S K. Modelling of drill–hole TEM responses from multiple targets covered by a conductive overburden[J]. Exploration Geophysics,1996,27:141−153.

[20] 宋汐瑾,党瑞荣,郭宝龙,等. 井中磁源瞬变电磁响应特征研究[J]. 地球物理学报,2011,54(4):1122−1129. SONG Xijin,DANG Ruirong,GUO Baolong,et al. Research on transient electromagnetic response of magnetic source in borehole[J]. Chinese Journal of Geophysics,2011,54(4):1122−1129.

[21] 张杰,王兴春,邓晓红,等. 地–井瞬变电磁井旁板状导体异常响应特征分析[J]. 物探化探计算技术,2014,36(6):641−648. ZHANG Jie,WANG Xingchun,DENG Xiaohong,et al. Borehole transient electromagnetic method response characteristics of the borehole–side plate–like conductor[J]. Computing Techniques for Geophysical and Geochemical Exploration,2014,36(6):641−648.

[22] 王鹏. 积水采空区地井瞬变电磁法探测[J]. 煤炭技术,2017,36(6):134−136. WANG Peng. Surface–hole TEM for detection of coal mine water collecting area[J]. Coal Technology,2017,36(6):134−136.

[23] 姚伟华,王鹏,李明星,等. 三分量地–孔瞬变电磁法积水采空区探测试验[J]. 煤田地质与勘探,2019,47(5):54−62. YAO Weihua,WANG Peng,LI Mingxing,et al. Experimental study of three–component down–hole TEM for detecting water–filled goaf[J]. Coal Geology & Exploration,2019,47(5):54−62.

[24] 姚伟华,王鹏,李明星,等. 地孔瞬变电磁法超前探测数值模拟响应特征[J]. 煤炭学报,2019,44(10):3145−3153. YAO Weihua,WANG Peng,LI Mingxing,et al. Numerical simulation response characteristics of down–hole TEM for advanced detection[J]. Journal of China Coal Society,2019,44(10):3145−3153.

[25] 王鹏,程建远,姚伟华,等. 积水采空区地面–钻孔瞬变电磁探测技术[J]. 煤炭学报,2019,44(8):2502−2508. WANG Peng,CHENG Jianyuan,YAO Weihua,et al. Technology of detecting water–filled goaf beside borehole using downhole transient electromagnetic method[J]. Journal of China Coal Society,2019,44(8):2502−2508.

[26] 李术才,李凯,翟明华,等. 矿井地面–井下电性源瞬变电磁探测响应规律分析[J]. 煤炭学报,2016,41(8):2024−2032. LI Shucai,LI Kai,ZHAI Minghua,et al. Analysis of grounded transient electromagnetic with surface–tunnel configuration in mining[J]. Journal of China Coal Society,2016,41(8):2024−2032.

[27] 武军杰,李貅,智庆全,等. 电性源地–井瞬变电磁异常场响应特征初步分析[J]. 物探与化探,2017,41(1):129−135. WU Junjie,LI Xiu,ZHI Qingquan,et al. A preliminary analysis of anomalous TEM response characteristics in borehole with electric source transmitter[J]. Geophysical & Geochemical Exploration,2017,41(1):129−135.

[28] 武军杰,李貅,智庆全,等. 电性源地–井瞬变电磁法三分量响应特征分析[J]. 地球物理学进展,2017,32(3):1273−1278. WU Junjie,LI Xiu,ZHI Qingquan,et al. Analysis of three component TEM response characteristic of electric source dill hole TEM[J]. Progress in Geophysics,2017,32(3):1273−1278.

[29] 武军杰,李貅,智庆全,等. 电性源地–井瞬变电磁全域视电阻率定义[J]. 地球物理学报,2017,60(4):1595−1605. WU Junjie,LI Xiu,ZHI Qingquan,et al. Full field apparent resistivity definition of borehole TEM with electric source[J]. Chinese Journal of Geophysics,2017,60(4):1595−1605.

[30] CHEN Weiying,KHAN M Y,XUE Guoqiang. Response of surface–to–borehole SOTEM method on two–dimensional earth[J]. Journal of Geophysics and Engineering,2017,14(4):987−997.

[31] 陈卫营,韩思旭,薛国强. 电性源地–井瞬变电磁法全分量响应特性与探测能力分析[J]. 地球物理学报,2019,62(5):1969−1980. CHEN Weiying,HAN Sixu,XUE Guoqiang. Analysis on the full–component response and detectability of electric source surface–to–borehole TEM method[J]. Chinese Journal of Geophysics,2019,62(5):1969−1980.

[32] 李凯,孙怀凤. 矿井含水构造地井瞬变电磁响应规律分析[J]. 中国矿业大学学报,2018,47(5):1113−1122. LI Kai,SUN Huaifeng. Response characteristics analysis of mine water filled structure with ground–tunnel transient electromagnetic method[J]. Journal of China University of Mining & Technology,2018,47(5):1113−1122.

[33] WANG Luyuan,YIN Changchun,LIU Yunhe,et al. Three–dimensional forward modeling for the SBTEM method using an unstructured finite–element method[J]. Applied Geophysics,2021,18(1):101−116.

[34] 赵华亮,张莹莹,吴国培,等. 电性源地–井瞬变电磁多分量全波形响应特征分析[J]. 地球物理学进展,2022,37(3):1235−1248. ZHAO Hualiang,ZHANG Yingying,WU Guopei,et al. Characteristic analysis of multi−component full−waveform responses of galvanic source surface−to−borehole TEM[J]. Progress in Geophysics,2022,37(3):1235−1248.

[35] 储韬玉. 矿井孔中瞬变电磁测量方法及其应用研究[D]. 徐州:中国矿业大学,2015.

CHU Taoyu. Study on the mine transient electromagnetic method in drilling and its application[D]. Xuzhou:China University of Mining and Technology,2015.

[36] 李学潜,韩德品,王程,等. 巷–孔瞬变电磁法在探测含导水构造中的应用[J]. 中国煤炭地质,2019,31(2):77−82. LI Xueqian,HAN Depin,WANG Cheng,et al. Application of roadway–borehole TEM in water–bearing and water conducting structure prospecting[J]. Coal Geology of China,2019,31(2):77−82.

[37] 赵睿,范涛,李宇腾,等. 钻孔瞬变电磁探测在水力压裂效果检测中的应用[J]. 煤田地质与勘探,2020,48(4):41−45. ZHAO Rui,FAN Tao,LI Yuteng,et al. Application of borehole transient electromagnetic detection in the test of hydraulic fracturing effect[J]. Coal Geology & Exploration,2020,48(4):41−45.

[38] 李世宁. 矿井巷孔瞬变电磁法应用研究[D]. 徐州:中国矿业大学,2016.

LI Shining. Study on the mine tunnel–drilling transient electromagnetic method and its application[D]. Xuzhou:China University of Mining and Technology,2016.

[39] 陈丁,程久龙,王阿明. 矿井全空间孔中瞬变电磁响应积分方程法数值模拟研究[J]. 地球物理学报,2018,61(10):4182−4193. CHEN Ding,CHENG Jiulong,WANG Aming. Numerical simulation of drillhole transient electromagnetic response in mine roadway whole space using integral equation method[J]. Chinese Journal of Geophysics,2018,61(10):4182−4193.

[40] 陈丁. 矿井全空间巷道孔中瞬变电磁波场特征数值模拟研究[D]. 北京:中国矿业大学(北京),2016.

CHEN Ding. Study on wave field characteristics of drillhole transient electromagnetic in mine roadway whole space using numerical simulation[D]. Beijing:China University of Mining and Technology (Beijing),2016.

[41] 吕荣其. 矿用孔中瞬变电磁探测装置及特性研究[D]. 徐州:中国矿业大学,2021.

LYU Rongqi. Research on transient electromagnetic detection device in mine hole and its characteristics[D]. Xuzhou:China University of Mining and Technology,2021.

[42] 张军. 钻孔瞬变电磁响应规律与水体定位研究[D]. 济南:山东大学,2020.

ZHANG Jun. Study on transient electromagnetic response characteristics of borehole and water body positioning[D]. Jinan:Shandong University,2020.

[43] 王世睿. 隧道掌子面–钻孔瞬变电磁超前探测方法与试验研究[D]. 济南:山东大学,2016.

WANG Shirui. Research on tunnel face–borehole transient electromagnetic method and experiment for advanced detection[D]. Jinan:Shandong University,2016.

[44] 孙怀凤,程铭,宿传玺,等. 隧(巷)道掘进工作面–钻孔瞬变电磁超前探测方法物理模拟试验研究[J]. 煤炭学报,2017,42(8):2110−2115. SUN Huaifeng,CHENG Ming,SU Chuanxi,et al. Tunnel face–borehole transient electromagnetic method and its physical experimental studies[J]. Journal of China Coal Society,2017,42(8):2110−2115.

[45] TAYLOR S,WOODS D V. Simple inversion methods to aid in the interpretation of borehole TEM data[C]//Society of Exploration Geophysicists. Seg Technical Program Expanded Abstracts 1985. 1985:33–135.

[46] FULLAGAR P K. Inversion of down-hole TEM data using circular current filaments[J]. Exploration Geophysics,1987,18:872−888.

[47] DUNCAN A C. Interpretation of down–hole transient EM data using current filaments[J]. Exploration Geophysics,1987,18:36−39.

[48] 杨毅,邓晓红,张杰,等. 一种井中瞬变电磁异常反演方法[J]. 物探与化探,2014,38(4):855−859. YANG Yi,DENG Xiaohong,ZHANG Jie,et al. A borehole TEM anomaly inversion method[J]. Geophysical and Geochemical Exploration,2014,38(4):855−859.

[49] 张杰,邓晓红,谭捍东,等. 地–井瞬变电磁资料矢量交会解释方法[J]. 物探与化探,2015,39(3):572−579. ZHANG Jie,DENG Xiaohong,TAN Handong,et al. A study of vector intersection for borehole transient electromagnetic method[J]. Geophysical & Geochemical Exploration,2015,39(3):572−579.

[50] 范涛. 矿井巷道–钻孔瞬变电磁二维拟地震反演方法及应用[J]. 煤炭学报,2019,44(6):1804−1816. FAN Tao. Method and application on 2D pseudo–seismic inversion of roadway–borehole transient electromagnetic detection in coal mine[J]. Journal of China Coal Society,2019,44(6):1804−1816.

[51] 范涛,李鸿泰,郭建磊,等. 钻孔瞬变电磁拟地震反演方法在露天煤矿采空区精细探测中的应用[J]. 地球科学与环境学报,2020,42(6):759−766. FAN Tao,LI Hongtai,GUO Jianlei,et al. Application of borehole transient electromagnetic pseudo–seismic inversion method in goaf fine detection of open–pit coal mine[J]. Journal of Earth Sciences and Environment,2020,42(6):759−766.

[52] 范涛,李萍,赵兆,等. 钻孔瞬变电磁方法探测越界开采采空区的应用[J]. 煤田地质与勘探,2022,50(1):20−24. FAN Tao,LI Ping,ZHAO Zhao,et al. Application of borehole transient electromagnetic method in detecting the cross–border mining goaf[J]. Coal Geology & Exploration,2022,50(1):20−24.

[53] 范涛,李鸿泰,刘磊,等. 基于聚类算法的钻孔瞬变电磁视电阻率立体成像方法[J]. 地球科学与环境学报,2021,43(2):343−355. FAN Tao,LI Hongtai,LIU Lei,et al. Stereo imaging method of borehole transient electromagnetic apparent resistivity based on clustering algorithm[J]. Journal of Earth Sciences and Environment,2021,43(2):343−355.

[54] 范涛,张幼振,赵睿,等. 基于钻孔TEM智能立体成像的快速掘进超前探测方法[J]. 煤炭学报,2021,46(2):578−590. FAN Tao,ZHANG Youzhen,ZHAO Rui,et al. Advance detection method of rapid excavation based on borehole TEM intelligent stereo imaging[J]. Journal of China Coal Society,2021,46(2):578−590.

[55] CHEN Weiying,HAN Sixu,KHAN M Y,et al. A surface–to–borehole TEM system based on grounded–wire sources:Synthetic modeling and data inversion[J]. Pure and Applied Geophysics,2020,177:4207−4216.

[56] MALECKI S,BÖRNER R U,SPITZER K. A new method for absolute underground positioning based on transient electromagnetics[J]. Geophysical Journal International,2020,221(1):87−96.

[57] 智庆全,武军杰,王兴春,等. 基于瞬变冲激时刻的地–井TEM快速定量解释方法[J/OL]. 煤田地质与勘探,2022:1–8 [2022-07-18]. http://kns. cnki. net/kcms/detail/61. 1155. P. 20220130. 1546. 004. html.

ZHI Qingquan,WU Junjie,WANG Xingchun,et al. Fast quantitative interpretation of surface–borehole TEM using transient impulse time[J/OL]. Coal Geology & Exploration,2022: 1–8 [2022-07-18]. http://kns. cnki. net/kcms/detail/61. 1155. P. 20220130. 1546. 004. html.

[58] 张运霞,韩自豪,周建雄,等. PROTEM67D瞬变电磁仪器在矿井水文地质勘探中的应用效果[J]. 工程地球物理学报,2005,2(2):123−128. ZHANG Yunxia,HAN Zihao,ZHOU Jianxiong,et al. The application effect of mining hydrogeological exploration using PROTEM67D system[J]. Chinese Journal of Engineering Geophysics,2005,2(2):123−128.

[59] KOZHEVNIKOV N O,ANTONOV E Y,KAMNEV Y K,et al. Effects of borehole casing on TEM response[J]. Russian Geology and Geophysics,2014,55(11):1333−1339.

[60] 蒋邦远,冯孟林,冶昭贤,等. 寻找深部隐伏矿的物化探综合方法技术研究[R]. 北京:中国地质科学院地球物理地球化学勘查研究所,1990.

[61] 胡平,石中英. 地–井TEM工作方法及解释技术研究成果报告[R]. 北京:中国地质科学院地球物理地球化学勘查研究所,1995.

[62] 胡平. 地–井瞬变电磁法(TEM)方法技术手册[R]. 北京:中国地质科学院地球物理地球化学勘查研究所,1995.

[63] 蒋邦远. 实用近区磁源瞬变电磁法勘探[M]. 北京:地质出版社,1998.

[64] 杨海燕,岳建华,胡文武,等. 多匝回线的自感对瞬变电磁早期信号的影响特征[J]. 物探化探计算技术,2007,29(2):96−98. YANG Haiyan,YUE Jianhua,HU Wenwu,et al. The characteristics of the early signal in TEM affected by self–induction of multi–turn coil[J]. Computing Techniques for Geophysical and Geochemical Exploration,2007,29(2):96−98.

[65] 姜志海,岳建华,刘树才. 多匝重叠小回线装置的矿井瞬变电磁观测系统[J]. 煤炭学报,2007,32(11):1152−1156. JIANG Zhihai,YUE Jianhua,LIU Shucai. Mine transient electromagnetic observation system of small multi–turn coincident configuration[J]. Journal of China Coal Society,2007,32(11):1152−1156.

[66] 苗彬,姜志海,刘树才. 矿井地面–巷道瞬变电磁探测系统设计及应用[J]. 煤炭科学技术,2016,44(12):148−153. MIAO Bin,JIANG Zhihai,LIU Shucai. Design and application of transient electromagnetic detection system on mine surface ground and in underground mine roadway[J]. Coal Science and Technology,2016,44(12):148−153.

[67] 林君,王琳,王晓光,等. 矿井瞬变电磁探测中空芯线圈传感器的研制[J]. 地球物理学报,2016,59(2):721−730. LIN Jun,WANG Lin,WANG Xiaoguang,et al. Research and development on the air–core coil sensor for mine transient electromagnetic exploration[J]. Chinese Journal of Geophysics,2016,59(2):721−730.

[68] 闫文超. 矿用孔–巷瞬变电磁仪关键技术研究[D]. 北京:煤炭科学研究总院,2018.

YAN Wenchao. Research on the key technology of the mine–used transient electromagnetic instrument for borehole and roadway[D]. Beijing:China Coal Research Institute,2018.

[69] 于景邨,苏本玉,薛国强,等. 煤层顶板致灾水体井上下双磁源瞬变电磁响应及应用[J]. 煤炭学报,2019,44(8):2356−2360. YU Jingcun,SU Benyu,XUE Guoqiang,et al. Transient electromagnetic response of double magnetic source in coal seam roof disaster caused by water and its application[J]. Journal of China Coal Society,2019,44(8):2356−2360.

[70] 于景邨,刘树才,王扬州. 巷道内金属体瞬变电磁响应特征及处理技术[J]. 煤炭学报,2008,33(12):1403−1407. YU Jingcun,LIU Shucai,WANG Yangzhou. Response characteristic of transient electromagnetic to metallic facilities in coal mines and the disposal technology[J]. Journal of China Coal Society,2008,33(12):1403−1407.

[71] BOYD G W,WILES C J. The Newmont drill–hole EMP system: Examples from eastern Australia[J]. Geophysics,1984,49(7):949−956.

[72] BISHOP J R,LEWIS R J G,MACNAE J C. Down–hole electromagnetic surveys at Renison Bell, Tasmania[J]. Exploration Geophysics,1987,18:265−277.

[73] EADIE T. The downhole EM response of the Hellyer ore deposit[J]. Exploration Geophysics,1987,18:255−264.

[74] MUTTON A J. Applications of downhole SIROTEM surveys in the Agnew Nickel belt, WA[J]. Exploration Geophysics,1987,18:295−303.

[75] LANE R J L. The downhole EM response of an intersected massive Sulphide deposit, South Australia[J]. Exploration Geophysics,1987,18:313−318.

[76] ASTEN M W,KING A,PEACOCK J. Sign changes in DHEM surveys for cindered coal in the Sydney Basin[J]. Exploration Geophysics,1987,18:319−323.

[77] HUGHES N A,RAVENHURST W. Three component DHEM surveying at Balcooma[J]. Exploration Geophysics,1996,27:77−89.

[78] VELLA L. Taking downhole EM underground,at hill 50 decline, mount magnet, western Australia[J]. Exploration Geophysics,1997,28:141−146.

[79] ELDERS J,WELLINGTON A. An application of reverse coupling to increase signal strength beneath conductive sediments–miitel mine, Kambalda,W. A[J]. Exploration Geophysics,1998,29:355−360.

[80] 崔霖沛,吴其斌. 寻找以铜为主的隐伏矿床的物探方法[R]. 北京:地质矿产信息研究院,1994.

[81] 国土资源部信息中心. 国外重要成矿区带典型找矿案例和勘查技术应用[M]. 北京,1999.

[82] 施俊法,姚华军,李友枝,等. 信息找矿战略与勘查百例[M]. 北京:地质出版社,2005.

[83] STOLZ E M G. Direct detection of gold bearing structures at St Ives,WA–DHEM vs DHMMR[J]. Exploration Geophysics,2003,34:131−136.

[84] 蒋慎君,陈卫. 金属矿区井中脉冲瞬变电磁法的应用效果[J]. 地质与勘探,1988,24(1):38−43. JIANG Shenjun,CHEN Wei. Drill hole TEM measurements in some mining districts[J]. Geology and Prospecting,1988,24(1):38−43.

[85] 张兆京,陈卫. 井中脉冲瞬变电磁法在栖霞山矿区初见成效[J]. 矿产与地质,1988,2(4):72−74. ZHANG Zhaojing,CHEN Wei. Pulse transient electromagnetic method in borehole has achieved initial success in Qixia mountain mining area[J]. Mineral Resources and Geology,1988,2(4):72−74.

[86] 张杰,邓晓红,郭鑫,等. 地–井TEM在危机矿山深部找矿中的应用实例[J]. 物探与化探,2013,37(1):30−34. ZHANG Jie,DENG Xiaohong,GUO Xin,et al. Typical cases of applying borehole TEM to deep prospecting in crisis mines[J]. Geophysical and Geochemical Exploration,2013,37(1):30−34.

[87] 钟明峰,张磊,童明慧,等. 地–井瞬变电磁在青海野马泉M1磁异常区金属矿勘探中的应用[J]. 矿产勘查,2019,10(7):1638−1644. ZHONG Mingfeng,ZHANG Lei,TONG Minghui,et al. Application of downhole transient electromagnetic method in metal exploration of M1 magnetic anomaly area in Yemaquan,Qinghai[J]. Mineral Exploration,2019,10(7):1638−1644.

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