Analysis of prospecting polymetallic metallogenic belts by comprehensive geophysical method

XIA Fan; SONG Hong-wei; WANG Meng; WANG Hong-liang; CHEN Yu

doi:DOI: 10.19637/j.cnki.2305-7068.2019.03.004

Volume 7 Issue 3

Sep. 2019

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Article Navigation > Journal of Groundwater Science and Engineering > 2019 > 7(3): 237-244

XIA Fan, SONG Hong-wei, WANG Meng, et al. 2019: Analysis of prospecting polymetallic metallogenic belts by comprehensive geophysical method. Journal of Groundwater Science and Engineering, 7(3): 237-244. doi: DOI: 10.19637/j.cnki.2305-7068.2019.03.004

Citation:

XIA Fan, SONG Hong-wei, WANG Meng, et al. 2019: Analysis of prospecting polymetallic metallogenic belts by comprehensive geophysical method. Journal of Groundwater Science and Engineering, 7(3): 237-244. doi: DOI: 10.19637/j.cnki.2305-7068.2019.03.004

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Analysis of prospecting polymetallic metallogenic belts by comprehensive geophysical method

doi: DOI: 10.19637/j.cnki.2305-7068.2019.03.004

1 Hebei Provincial Academy of Environmental Sciences, Shijiazhuang 050031, China. 2Institute of Hydrogeology and Environmental Geology, CAGS, Shijiazhuang 050061, China. 3Geophysical Exploration Academy of China Metallurgical Geology Bureau, Baoding, Hebei Province 071051, China.

Publish Date: 2019-09-28

Abstract

Abstract

This paper is based on the analysis and research on the silver-lead-zinc polymetallic ore in New Ballyhoo Banner in southern Manzhouli of Inner Mongolia. Because metal mineralization brings rock formations，the geophysical features such as low resistivity, high polarization rate and uneven distribution of magnetization, the comprehensive geophysical methods are adopted including high-precision magnetic measurement, high-power induced polarization, IP field middle gradient and controlled source audio-frequency magnetotellurics. In the survey work of multi-metal ore deposits, from surface sweeping to single point measurement, and from single point to section going deeper layer by layer, the resolution of measurement is continuously improved, and various geophysical methods support and complement each other, so explorers can successfully predict the direction, scale and volume of the metallogenic belts in conjunction with geochemical exploration, geological survey and drilling. It has provided a strong basis for completing the exploration task of predicting the reserve volume of ore bodies. The research conclusions of this exploration case have thus a high reference value in the same type of exploration work.

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References(11)

References

SONG Hong-wei, MU Hai-dong, XIA Fan. 2018. Analyzing the differences of brackish-water in the Badain Lake by geophysical exploration method. Journal of Goundwater Science and Egineering, 3(6): 187-192.

YAN Jian-min, ZHAI Cai-lan, et al. 2008. The example of electric prospecting used in the metallic mineral resources prospecting. Petroleum Instruments, 22(5): 80-83.

YAN Chong-wei, LI Wen-yao, et al. 2016. Application of geophysics method in the exploration of New Baerhu Flag Moly Mine in Inner Mongolia. Modern Mining, (568): 146-151.

JIN Zheng, LIU Zhen-hua, TIAN Nan. 2014. The application of high power induced polarization in New Baerhu Right Flag Metallogenic Area. Science & Technology Vision: 162-163.

LI Di-quan, WANG Guang-jie, et al. 2007. The application of high-power induced polari-zation in the Middle Section of Eerguna Metallogenic Belt. Progress in Geophysics, 22(5): 1621-1626.

LIU Guo-hui, ZHANG Xian-min, JIA Xue-min. 2007. New technology of groundwater re-sources electrical prospecting. Beijing: Earthquake Press: 60-64.

GUO Yu-fu, JIANG Li-ying, et al. 2005. Some cases on IP prospecting. Jilin Geology, 24(4): 105-110.

ZHAO Tian-ping. 2008. Practical application of induced polarization for prospecting hidden copper multimetal deposit. Gansu Geology, 17(2): 85-88.

LI Jin-ming. 2005. Electric field and electrical prospecting. Beijing: Geology Press: 208-215.

ZHAO Wei-xin, YU Chun, ZANG Yi-qi. 2012. The application of high power induced polarization in the section of Zhang Jiashan Metallogenic Belt. Acta Geologica Sichuan, (32): 75-77.

ZHANG Hui, XIE Ling-lin, WU Xiang-bin. 2008. Application of audio magnetotellurics and high-power induced polarization for prospecting the concealed ores in the Eerguna Metallogenic Belt. Geology and Prospecting, 44(5): 77-80.

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