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Haohui, W., Yajuan, Y., Shanshan, L., & Kai, H. (2018). An empirical study of the assessment of green development in beijing, china: considering resource depletion, environmental damage and ecological benefits simultaneously. Sustainability, 10(3), 719.Search in Google Scholar
Sun, Y., Li, Y., Yu, T., Zhang, X., Liu, L., & Zhang, P. (2021). Resource extraction, environmental pollution and economic development: evidence from prefecture-level cities in china. Resources Policy, 74.Search in Google Scholar
Cibulka, S., & Giljum, S. (2020). Towards a comprehensive framework of the relationships between resource footprints, quality of life, and economic development. Sustainability.Search in Google Scholar
Mazumder, P., Das, A., Khwairakpam, M., & Kalamdhad, A. S. (2021). A comprehensive insight into ecological risk assessment and remediation of metal contaminated coal mine soil: towards a cleaner and sustainable environment. Journal of cleaner production(Nov.15), 324.Search in Google Scholar
Cao, L., Xiang, H., Yang, P., Zhang, Z., He, C., & Lin, C., et al. (2022). Towards sustainable and efficient land development: risk of soil heavy metal(loid)s in abandoned gold mines with short‐term rehabilitation and potential value for targeted remediation. Land Degradation & Development, 33, 3855 - 3869.Search in Google Scholar
Wu, YW, Zhang, JC, Guo, & XP. (2017). An indigenous soil bacterium facilitates the mitigation of rocky desertification in carbonate mining areas. Land Degrad Dev.Search in Google Scholar
Ji, J., Wang, S., Zhou, Y., Liu, W., & Wang, L. (2021). Spatiotemporal change and coordinated development analysis of “population-society-economy-resource-ecology- environment” in the jing-jin-ji urban agglomeration from 2000 to 2015. Sustainability, 13(7), 4075.Search in Google Scholar
Zhang, Y., Chen, M., Zhao, Y. Y., Zhang, A. Y., Peng, D. H., & Lu, F., et al. (2021). Destruction of the soil microbial ecological environment caused by the over-utilization of the rice-crayfish co-cropping pattern. Science of The Total Environment.Search in Google Scholar
Ndubisi, N. O., Alshuridah, O., & Capel, C. (2020). Greening multinational enterprises in the oil, gas and petrochemicals: environmental sustainability and the moderation role of environmental sensitivity. International Journal of Manpower, 41.Search in Google Scholar
Zhengxin, J. I., Liu, C., Yueqing, X. U., Sun, M., Wei, H., & Sun, D., et al. (2023). Quantitative identification and the evolution characteristics of production-living-ecological space in the mountainous area: from the perspective of multifunctional land. Journal of Geographical Sciences, 33(4), 779-800.Search in Google Scholar
Liu, Y., Gao, T., Wang, X., Fu, J., Zuo, M., & Yang, Y., et al. (2022). Effects of heavy metals on bacterial community surrounding bijiashan mining area located in northwest china. Open life sciences, 17(1), 40-54.Search in Google Scholar
Fois, M., Murgia, L., & Bacchetta, G. (2023). Plant diversity and species composition of the abandoned mines of the iglesiente mining district (sardinia, italy): a restoration perspective. Ecological Engineering, 188, 106879-.Search in Google Scholar
Yinli, B., Kun, W., & Jin, W. (2018). Effect of different inoculation treatments on am fungal communities and the sustainability of soil remediation in daliuta coal mining subsidence area in northwest china. Applied Soil Ecology, 132, S0929139318302348-.Search in Google Scholar
Mckenna, P. B., Lechner, A., Phinn, S., & Erskine, P. (2020). Remote sensing of mine site rehabilitation for ecological outcomes: a global systematic review. Remote Sensing.Search in Google Scholar
Ma, T., Luo, H., Huang, K., Pan, Y., Tang, T., & Tao, X., et al. (2021). Integrated ecological risk assessment of heavy metals in an oil shale mining area after restoration. Journal of environmental management, 300, 113797.Search in Google Scholar
Novianti, V., Marrs, R. H., Choesin, D. N., Iskandar, D. T., & Suprayogo, D. (2018). Natural regeneration on land degraded by coal mining in a tropical climate: lessons for ecological restoration from indonesia. Land Degradation and Development.Search in Google Scholar
Estefanía, Bonnail, Francisco, Macías, Victoria, & Osta. (2018). Ecological improvement assessment of a passive remediation technology for acid mine drainage: water quality biomonitoring using bivalves. Chemosphere.Search in Google Scholar
A, C. L., A, Z. J., A, X. P., B, L. Z., C, B. Z., & A, X. L., et al. (2020). Functions of mineral-solubilizing microbes and a water retaining agent for the remediation of abandoned mine sites. Science of the Total Environment.Search in Google Scholar
Lahori, A. H., Ping, W., Shuncheng, J., Zhanyu, G., Zengqiang, Z., & Ronghua, L. I., et al. (2017). Use of biochar as an amendment for remediation of heavy metal-contaminated soils: prospects and challenges. Pedosphere, 027(006), 991-1014.Search in Google Scholar
Li, L., Zhang, J., Lu, S., Lu, H., Du, Z., & Bi, B., et al. (2023). Performance of wetland applied to ecological remediation of abandoned fish ponds: a case study in gonghu bay, tai lake. Chemosphere, 316, 137698.Search in Google Scholar
