Monitoring Mining-Induced Geo-Hazards in a Contaminated Mountainous Region of Indonesia Using Satellite Imagery

Remote. Sens. Pub Date : 2023-07-07 DOI:10.3390/rs15133436
Satomi Kimijima, M. Nagai
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Abstract

Mining-induced or enhanced geo-hazards (MGHs) pose significant risks in rural mountainous regions with underground mining operations by harming groundwater layers, water circulation systems, and mountain stability. MGHs occurring in naturally contaminated environments can severely amplify socio-environmental risks. A high correlation was found among undermining development, precipitation, and hazards; however, details of MGHs have yet to be adequately characterized. This study investigated multiple mining-induced/enhanced geo-hazards in a naturally contaminated mountain region in Bone Bolango Regency, Gorontalo Province, Indonesia, in 2020, where a rapidly developing coexisting mining sector was present. We utilized PlanetScope’s CubeSat constellations and Sentinel-1 dataset to assess the volume, distribution, pace, and pattern of MGHs. The findings reveal that severe landslides and floods accelerated the mobilization of potentially toxic elements (PTEs) via the river water system, thus considerably exacerbating socio-environmental risks. These results indicate potential dangers of enhanced PTE contamination for marine ecosystems and humans at a regional level. The study design and data used facilitated a comprehensive assessment of the MGHs and associated risks, providing important information for decision-makers and stakeholders. However, limitations in the methodology should be considered when interpreting the findings. The societal benefits of this study include informing policies and practices that aim to mitigate the negative impacts of mining activities on the environment and society at the local and regional levels.
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利用卫星图像监测印度尼西亚受污染山区采矿诱发的地质灾害
采矿诱发或增强型地质灾害(MGHs)通过破坏地下水层、水循环系统和山区稳定,对农村山区地下采矿作业构成重大风险。发生在自然污染环境中的MGHs可严重放大社会环境风险。破坏发育与降水、危害高度相关;然而,MGHs的细节尚未得到充分的描述。本研究于2020年在印度尼西亚哥龙塔洛省Bone Bolango Regency的一个自然污染山区调查了多种采矿诱发/增强的地质灾害,该地区存在快速发展的共存采矿部门。我们利用PlanetScope的CubeSat星座和Sentinel-1数据集来评估MGHs的数量、分布、速度和模式。研究结果表明,严重的山体滑坡和洪水加速了潜在有毒元素(pte)通过河流水系的调动,从而大大加剧了社会环境风险。这些结果表明,在区域层面上,PTE污染加剧对海洋生态系统和人类的潜在危险。研究设计和使用的数据促进了对MGHs和相关风险的全面评估,为决策者和利益相关者提供了重要信息。然而,在解释研究结果时应考虑方法的局限性。这项研究的社会效益包括为旨在减轻地方和区域一级采矿活动对环境和社会的负面影响的政策和做法提供信息。
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