罗马尼亚Zlatna金矿矿区矿区水的成因、地球化学特征及其对地下水和地表水的影响

IF 1.7 4区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS
Delia Cristina Papp, Ioan Cociuba, Călin Baciu, Alexandra Cozma
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引用次数: 9

摘要

在Zlatna金矿区(罗马尼亚Apuseni Mountains)的应用中,成功地利用水同位素相关性和地球化学数据来评估地表水、地下水和矿井水之间的成因关系,并评估采矿作业停止后对周围环境的影响。大部分矿井水源的pH值在4 ~ 5之间,即酸性矿井水。pH值略高(6)的矿井水与蛇绿岩相互作用,蛇绿岩具有较高的pH缓冲能力。中性矿井水(pH?(7)不与活性矿物直接接触,要么是因为它从勘探坑道中排放出来,要么是因为黄铁矿和其他硫化物在废弃的旧矿山中完全浸出。后者也显示出低水平的重金属浓度。钙离子是矿水和大多数地表水和地下水中的主要阳离子,表明了相同的矿化机制。矿井水源均为\(\text{SO}_{4}^{2 - }\)型,\(\text{SO}_{4}^{2 - }\)浓度非常高(6539?Mg /l平均值)。地表水和地下水水源被分类为\(\text{SO}_{4}^{2 - }\)或\(\text{HCO}_{3}^{ - }\)型水。δD值与δ18O值呈线性相关,表明所有水源都属于大气循环。矿井水δD和δ18O值低(δD &lt;? 70‰;δ18O?&lt;? 10‰)表明融雪和高海拔降水是补给的主要来源。矿井水受温度季节变化的影响较小。在大多数情况下,同位素组成的变化范围很窄(δD和δ18O均小于1‰),这表明地下系统混合良好。矿井水中硫酸盐、锌和铁的浓度升高是主要问题。研究区未发现泉水和地下水受到矿井水的相关污染。相反,地表水受到矿井水的污染,酸性矿井水的负面影响主要发生在夏季地表水流量减少的月份。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Origin and Geochemistry of Mine Water and its Impact on the Groundwater and Surface Running Water in Post-mining Environments: Zlatna Gold Mining Area (Romania)

Origin and Geochemistry of Mine Water and its Impact on the Groundwater and Surface Running Water in Post-mining Environments: Zlatna Gold Mining Area (Romania)

In application at the Zlatna gold mining area (Apuseni Mountains, Romania), the correlation of water isotopes and geochemical data were successfully used to assess the genetic relationships between surface running water, groundwater and mine water, as well as to evaluate the mining effects on the surrounding environment after the cessation of mining operations. The majority of mine water sources display pH values between 4 and 5, i.e. acid mine water. The mine water characterized by slightly higher pH values (~6) interacts with ophiolitic rocks which have high pH buffering capacity. The neutral mine water (pH?~?7) does not come into direct contact with reactive minerals, either because it is discharged from an exploration adit or because of the complete leaching of pyrite and other sulphides in old abandoned mining works. The later also shows low levels of heavy metals concentrations. Calcium is the dominant cation in mine water and in the majority of surface running water and groundwater sources, indicating the same mechanisms of mineralization. All mine water sources are \(\text{SO}_{4}^{2 - }\) type and show very high \(\text{SO}_{4}^{2 - }\) concentrations (6539?mg/l mean value). Surface and groundwater sources are classified either as \(\text{SO}_{4}^{2 - }\) or as \(\text{HCO}_{3}^{ - }\) type water. Linear correlation between δD and δ18O values indicates that all water sources belong to the meteoric cycle. Low δD and δ18O values of mine water (δD?<??70‰; δ18O?<??10‰) suggest snow melt and high-altitude precipitations as the main source of recharge. The mine water is less affected by the seasonal variation of temperature. In most cases, the variations in isotopic composition are within narrow limits (less than 1‰ for both δD and δ18O), and this result suggests well-mixed underground systems. Elevated concentration of sulphates, Zn and Fe in mine waters are the main issues of concern. For the study area, no relevant contamination of springs or phreatic water by mine water was revealed. On the contrary, surface running water is contaminated by mine water, and the negative effects of acid mine drainage occur mainly in the summer months when the flow of the surface running water decreases.

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来源期刊
Aquatic Geochemistry
Aquatic Geochemistry 地学-地球化学与地球物理
CiteScore
4.30
自引率
0.00%
发文量
6
审稿时长
1 months
期刊介绍: We publish original studies relating to the geochemistry of natural waters and their interactions with rocks and minerals under near Earth-surface conditions. Coverage includes theoretical, experimental, and modeling papers dealing with this subject area, as well as papers presenting observations of natural systems that stress major processes. The journal also presents `letter''-type papers for rapid publication and a limited number of review-type papers on topics of particularly broad interest or current major controversy.
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