Based on remote sensing technology, the authors investigated the distribution of tailings reservoir in Tibet, such as its mineral resources, utilization status and scale. The current mining intensity of different administrative regions, different metallogenic belts and different mine types in Tibet was analyzed. Some conclusions have been reached: for different prefectural-level divisions, the metal mines’ mining intensity in Lhasa City is the largest, the metal mines exploitation potential in Lhasa City and Naqu area are larger. For different county-level administrative regions, the metal mines mining intensity in Mozhugongka County of Lhasa City is the largest, the metal mines exploitation potential in Mozhugongka County of Lhasa City and Shenzha County of Naqu area are larger. For different important metallogenic belts, the metal mines mining intensity in Gangdise metallogenic belt is the largest, the metal mines exploitation potential in Gangdise metallogenic belt is also the largest. For different mine types, the metal mines mining intensity of nonferrous minerals is the largest, the metal mines exploitation potential of nonferrous minerals is also the largest. For different specific mine types, the metal mines mining intensity of lead-zinc mines and copper mines are the largest, and the metal mines exploitation potentialof lead-zinc mines is the largest.
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Haiqing WANG, Li LI, Ling CHEN, Wenjia XU, Jinzhong YANG, Qiong LIU. An analysis of mining intensity about metal mines based on investigation of tailing reservoirs in Tibet. Remote Sensing for Land & Resources, 2019, 31(2): 218-223.
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