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Remote Sensing for Land & Resources    2020, Vol. 32 Issue (1) : 232-236     DOI: 10.6046/gtzyyg.2020.01.31
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Remote sensing monitoring of mine geological environment in Zhejiang Province based on RS and GIS
Jie WANG1, Yaqiu YIN1, Hang YU1, Cunhao JIANG1, Yu WAN2
1. China Aero Geophysical Survey and Remote Sensing Center for Natural Resources, Beijing 100083, China
2. School of the Earth Sciences and Resources, China University of Geosciences(Beijing), Beijing 100083, China
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Abstract  

Taking the two-year high-resolution satellite image data obtained in 2016 and 2017 as the information source, the authors processed the data of two-year remote sensing image, established the mine remote sensing interpretation mark according to the image features, and verified some map-spots in the field of Zhejiang Province. Remote sensing investigation and dynamic monitoring of the geological environment and restoration of mines in Zhejiang Province were carried out in the natural environment and topography. Through the application research, the status and the changing trend of the mine geological environment in the mining area have been clarified, which can provide a scientific basis for the government departments to formulate the decision for the next step of mine geological environment restoration and management as well as the rational development and utilization of mineral resources.

Keywords domestic high-resolution satellite      remote sensing monitoring      mine geological environment      mine recovery and treatment     
:  TP79  
Issue Date: 14 March 2020
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Jie WANG
Yaqiu YIN
Hang YU
Cunhao JIANG
Yu WAN
Cite this article:   
Jie WANG,Yaqiu YIN,Hang YU, et al. Remote sensing monitoring of mine geological environment in Zhejiang Province based on RS and GIS[J]. Remote Sensing for Land & Resources, 2020, 32(1): 232-236.
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https://www.gtzyyg.com/EN/10.6046/gtzyyg.2020.01.31     OR     https://www.gtzyyg.com/EN/Y2020/V32/I1/232
Fig.1  Terrain gradient map in Zhejiang Province
Fig.2  Overall technical flow chart
Fig.3  Example of iron ore mine land occupation
Fig.4  Example of open-cut limestone mine
Fig.5  Example of restored mine
矿山环境状况 占地类型 年份
2016年 2017年
挖损土地 采场 15 534.11 14 973.87
压占土地 中转场地 5 873.99 5 865.10
固体废弃物 340.32 437.26
矿山建筑 459.24 457.62
塌陷土地 塌陷坑 0.49 0.49
恢复治理 恢复治理 6 519.13 7 839.95
合计 28 727.28 29 574.29
Tab.1  Remote sensing survey statistics of mine geological environment and recovery management in Zhejiang(hm2)
Fig.6  Statistics of land types after the restoration of mines in Zhejiang Province from 2016 to 2017
地级行政区 县级行政区 崩塌数量 塌陷区数量
宁波市 余姚市 1 0
金华市 兰溪市 1 0
衢州市 衢江区 1 0
龙游县 0 1
台州市 黄岩区 1 0
路桥区 1 0
临海市 2 0
合计 7 1
Tab.2  Remote sensing statistics of mine geological hazards in Zhejiang Province(处)
Fig.7  Changes of mine geological disasters from 2016 to 2017
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