4.12.8.2.4 Mine Reclamation, Mine Remediation, Restoration, Mining Restoration

Chapter Contents (Back)
Mine Reclamation. Mine Restoration. Mining Restoration.

Zhang, H.[Hao], Mendoza-Sanchez, I., Miller, E.L., Abriola, L.M.,
Manifold Regression Framework for Characterizing Source Zone Architecture,
GeoRS(54), No. 1, January 2016, pp. 3-17.
IEEE DOI 1601
contaminated site remediation. Other contamination. BibRef

Padmanaban, R.[Rajchandar], Bhowmik, A.K.[Avit K.], Cabral, P.[Pedro],
A Remote Sensing Approach to Environmental Monitoring in a Reclaimed Mine Area,
IJGI(6), No. 12, 2017, pp. xx-yy.
DOI Link 1801
BibRef

Xiao, W.[Wu], Deng, X.Y.[Xin-Yu], He, T.T.[Ting-Ting], Chen, W.Q.[Wen-Qi],
Mapping Annual Land Disturbance and Reclamation in a Surface Coal Mining Region Using Google Earth Engine and the LandTrendr Algorithm: A Case Study of the Shengli Coalfield in Inner Mongolia, China,
RS(12), No. 10, 2020, pp. xx-yy.
DOI Link 2006
BibRef

Szostak, M.[Marta], Pietrzykowski, M.[Marcin], Likus-Cieslik, J.[Justyna],
Reclaimed Area Land Cover Mapping Using Sentinel-2 Imagery and LiDAR Point Clouds,
RS(12), No. 2, 2020, pp. xx-yy.
DOI Link 2001
BibRef

Szostak, M.[Marta], Likus-Cieslik, J.[Justyna], Pietrzykowski, M.[Marcin],
PlanetScope Imageries and LiDAR Point Clouds Processing for Automation Land Cover Mapping and Vegetation Assessment of a Reclaimed Sulfur Mine,
RS(13), No. 14, 2021, pp. xx-yy.
DOI Link 2107
BibRef

Fan, X.[Xiang], Song, Y.Z.[Yong-Ze], Zhu, C.X.[Chu-Xin], Balzter, H.[Heiko], Bai, Z.K.[Zhong-Ke],
Estimating Ecological Responses to Climatic Variability on Reclaimed and Unmined Lands Using Enhanced Vegetation Index,
RS(13), No. 6, 2021, pp. xx-yy.
DOI Link 2104
BibRef

Wang, Q.Y.[Qi-Yuan], Zhao, Y.L.[Yan-Ling], Yang, F.F.[Fei-Fei], Liu, T.[Tao], Xiao, W.[Wu], Sun, H.Y.[Hai-Yuan],
Simulating Heat Stress of Coal Gangue Spontaneous Combustion on Vegetation Using Alfalfa Leaf Water Content Spectral Features as Indicators,
RS(13), No. 13, 2021, pp. xx-yy.
DOI Link 2107
Coal mine reclamation areas. BibRef

Wang, W.[Wei], Liu, R.Y.[Rong-Yuan], Gan, F.P.[Fu-Ping], Zhou, P.[Ping], Zhang, X.W.[Xiang-Wen], Ding, L.[Ling],
Monitoring and Evaluating Restoration Vegetation Status in Mine Region Using Remote Sensing Data: Case Study in Inner Mongolia, China,
RS(13), No. 7, 2021, pp. xx-yy.
DOI Link 2104
BibRef

Jeong, Y.[Yongsik], Yu, J.[Jaehyung], Wang, L.[Lei], Huynh, H.H.[Huy Hoa], Kim, H.C.[Hyun-Cheol],
Monitoring Asbestos Mine Remediation Using Airborne Hyperspectral Imaging System: A Case Study of Jefferson Lake Mine, US,
RS(14), No. 21, 2022, pp. xx-yy.
DOI Link 2212
BibRef

Dai, X.O.[Xia-Oai], Li, W.Y.[Wen-Yu], Liu, Z.L.[Zhi-Long], Tong, C.[Chenbo], Li, C.[Cheng], Zeng, J.W.[Jian-Wen], Ye, Y.K.[Ya-Kang], Li, W.[Weile], Shan, Y.F.[Yun-Feng], Zhou, J.Y.[Jia-Yun], Zhang, J.J.[Jun-Jun], Xu, L.[Li], Jiang, X.L.[Xiao-Li], Ruan, H.[Huihua], Zhang, J.B.[Jin-Biao], Huang, W.[Wei],
Effects of Mining on Urban Environmental Change: A Case Study of Panzhihua,
RS(14), No. 23, 2022, pp. xx-yy.
DOI Link 2212
BibRef

Wang, Q.Y.[Qi-Yuan], Zhao, Y.L.[Yan-Ling], Xiao, W.[Wu], Lin, Z.H.[Zi-Han], Ren, H.[He],
Assessing Potential Spontaneous Combustion of Coal Gangue Dumps after Reclamation by Simulating Alfalfa Heat Stress Based on the Spectral Features of Chlorophyll Fluorescence Parameters,
RS(14), No. 23, 2022, pp. xx-yy.
DOI Link 2212
BibRef

Han, J.Z.[Jia-Zheng], Hu, Z.Q.[Zhen-Qi], Mao, Z.[Zhen], Li, G.S.[Gen-Sheng], Liu, S.G.[Shu-Guang], Yuan, D.Z.[Dong-Zhu], Guo, J.X.[Jia-Xin],
How to Account for Changes in Carbon Storage from Coal Mining and Reclamation in Eastern China? Taking Yanzhou Coalfield as an Example to Simulate and Estimate,
RS(14), No. 9, 2022, pp. xx-yy.
DOI Link 2205
BibRef

Buczynska, A.[Anna], Blachowski, J.[Jan], Bugajska-Jedraszek, N.[Natalia],
Analysis of Post-Mining Vegetation Development Using Remote Sensing and Spatial Regression Approach: A Case Study of Former Babina Mine (Western Poland),
RS(15), No. 3, 2023, pp. xx-yy.
DOI Link 2302
BibRef

Zhang, P.P.[Pei-Pei], Chen, X.[Xidong], Ren, Y.[Yu], Lu, S.Q.[Si-Qi], Song, D.W.[Dong-Wei], Wang, Y.[Yingle],
A Novel Mine-Specific Eco-Environment Index (MSEEI) for Mine Ecological Environment Monitoring Using Landsat Imagery,
RS(15), No. 4, 2023, pp. xx-yy.
DOI Link 2303
BibRef

Blachowski, J.[Jan], Dynowski, A.[Aleksandra], Buczynska, A.[Anna], Ellefmo, S.L.[Steinar L.], Walerysiak, N.[Natalia],
Integrated Spatiotemporal Analysis of Vegetation Condition in a Complex Post-Mining Area: Lignite Mine Case Study,
RS(15), No. 12, 2023, pp. xx-yy.
DOI Link 2307
BibRef

Hong, F.Z.[Fang-Zhou], He, G.J.[Guo-Jin], Wang, G.Z.[Gui-Zhou], Zhang, Z.M.[Zhao-Ming], Peng, Y.[Yan],
Monitoring of Land Cover and Vegetation Changes in Juhugeng Coal Mining Area Based on Multi-Source Remote Sensing Data,
RS(15), No. 13, 2023, pp. 3439.
DOI Link 2307
BibRef

Silva, M.[Manuel], Hermosilla, G.[Gabriel], Villavicencio, G.[Gabriel], Breul, P.[Pierre],
Automated Detection and Analysis of Massive Mining Waste Deposits Using Sentinel-2 Satellite Imagery and Artificial Intelligence,
RS(15), No. 20, 2023, pp. 4949.
DOI Link 2310
BibRef

Chen, Y.[Yanan], Yan, F.[Fuli], Chen, J.[Jian], Fan, X.T.[Xiang-Tao],
Detection Ground Deformation Characteristics of Reclamation Land with Time-Series Interferometric Synthetic Aperture Radar in Tianjin Binhai New Area, China,
RS(15), No. 22, 2023, pp. 5303.
DOI Link 2311
BibRef

Wang, Y.F.[Yan-Fang], Zhao, S.[Shan], Zuo, H.[Hengtao], Hu, X.[Xin], Guo, Y.[Ying], Han, D.[Ding], Chang, Y.[Yuejia],
Tracking the Vegetation Change Trajectory over Large-Surface Coal Mines in the Jungar Coalfield Using Landsat Time-Series Data,
RS(15), No. 24, 2023, pp. 5667.
DOI Link 2401
BibRef

Micha?owska, K.[Krystyna], Pirowski, T.[Tomasz], G?owienka, E.[Ewa], Szypu?a, B.[Bart?omiej], Malinverni, E.S.[Eva Savina],
Sustainable Monitoring of Mining Activities: Decision-Making Model Using Spectral Indexes,
RS(16), No. 2, 2024, pp. 388.
DOI Link 2402
BibRef

Ren, H.[He], Zhao, Y.L.[Yan-Ling], Xiao, W.[Wu], Zhang, L.[Lifan],
Unmanned Aerial Vehicle (UAV)-Based Vegetation Restoration Monitoring in Coal Waste Dumps after Reclamation,
RS(16), No. 5, 2024, pp. 881.
DOI Link 2403
BibRef

Ding, C.[Chao], Feng, G.C.[Guang-Cai], Xiong, Z.Q.[Zhi-Qiang], Zhang, L.[Lu],
Ground Subsidence, Driving Factors, and Risk Assessment of the Photovoltaic Power Generation and Greenhouse Planting (PPG&GP) Projects in Coal-Mining Areas of Xintai City Observed from a Multi-Temporal InSAR Perspective,
RS(16), No. 6, 2024, pp. 1109.
DOI Link 2403
BibRef

Guo, L.[Li], Li, J.[Jun], Zhang, C.[Chengye], Xu, Y.L.[Ya-Ling], Xing, J.[Jianghe], Hu, J.Y.[Jing-Yu],
Evaluating the Impact of Human Activities on Vegetation Restoration in Mining Areas Based on the GTWR,
IJGI(13), No. 4, 2024, pp. 132.
DOI Link 2405
BibRef


Fletcher, A.T., Erskine, P.D.,
Rehabilitation Closure Criteria Assessment Using High Resolution Photogrammetrically Derived Surface Models,
UAV-g13(137-140).
DOI Link 1311
Recovery of mined areas. BibRef

Chapter on Computational Vision, Regularization, Connectionist, Morphology, Scale-Space, Perceptual Grouping, Wavelets, Color, Sensors, Optical, Laser, Radar continues in
Surface Deformation, Subsidance From SAR Applied in Urban, City Areas .


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