利用三维建模和随机森林预测深部矿藏潜力:中国西藏熊村斑岩型铜金矿床案例研究

IF 2.8 3区 地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY Mathematical Geosciences Pub Date : 2024-07-29 DOI:10.1007/s11004-024-10151-8
Yuming Lou, Xinghai Lang, Xu Kang, Jiansheng Gong, Kai Jiang, Shirong Dou, Difei Zhou, Zhaoshuai Wang, Shuyue He
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引用次数: 0

摘要

与大范围的区域勘探相比,深入已知矿藏或历史矿山勘探发现隐藏矿藏的几率更高。机器学习算法和三维建模可以有效识别深部目标,并对潜在资源进行定量预测。本研究论文介绍了一种拟议的工作流程,该流程利用随机森林算法和三维模型,结合地层、岩性、蚀变和原生晕等地质因素,提高勘探预测的准确性。该研究从熊村 2 号矿床 8 条勘探线的 34 个钻孔中采集了 7949 个岩石样本,并对 18 种元素进行了地球化学分析计算。所采用的方法可归纳如下:(1) 建立和预处理熊村 2 号矿床的地质数据集,然后进行多元统计分析;(2) 划分原生晕带序,以确定更大深度的潜在矿化;(3) 结合地质和地球化学成矿信息构建三维模型;(4) 利用随机森林算法提取勘探标准,定量预测深部勘探目标。结果表明,在 2 号矿床西北偏西 300 米处,控制深度向下延伸范围内有一处重要矿化物。目标区域的三维模型显示,该区域存在约 33 万吨铜(Cu)、7.6 吨金(Au)和 22.8 吨银(Ag)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Using Three-dimensional Modeling and Random Forests to Predict Deep Ore Potentials: A Case Study on Xiongcun Porphyry Copper–Gold Deposit in Tibet, China

The chances of discovering hidden deposits are higher when exploring deeper into known deposits or historic mines, compared to broad-scale regional exploration. Machine learning algorithms and three-dimensional modeling can effectively identify deep targets and provide quantitative predictions of potential resources. This research paper presents a proposed workflow that utilizes random forest algorithms and a three-dimensional model incorporating geological factors such as strata, lithology, alteration, and primary halo to enhance the accuracy of exploration predictions. The study involved collecting 7949 rock samples from 34 boreholes in eight exploration lines at the Xiongcun No. 2 deposit, and performing geochemical analysis calculations on 18 elements. The methodologies employed can be summarized as follows: (1) establishing and preprocessing the geological dataset of the Xiongcun No. 2 deposit, followed by multivariate statistical analysis, (2) delineating primary halo zoning sequences to identify potential mineralization at greater depths, (3) constructing three-dimensional models incorporating geological and geochemical mineralization information, and (4) utilizing the random forest algorithm to extract exploration criteria and quantitatively predict deep exploration targets. The results indicate a significant mineralization located 300 m to the west–northwest of the No. 2 deposit, within the downward extension of the control depth. The three-dimensional model of the target volume reveals the presence of approximately 0.33 million tons of copper (Cu), 7.6 tons of gold (Au), and 22.8 tons of silver (Ag).

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来源期刊
Mathematical Geosciences
Mathematical Geosciences 地学-地球科学综合
CiteScore
5.30
自引率
15.40%
发文量
50
审稿时长
>12 weeks
期刊介绍: Mathematical Geosciences (formerly Mathematical Geology) publishes original, high-quality, interdisciplinary papers in geomathematics focusing on quantitative methods and studies of the Earth, its natural resources and the environment. This international publication is the official journal of the IAMG. Mathematical Geosciences is an essential reference for researchers and practitioners of geomathematics who develop and apply quantitative models to earth science and geo-engineering problems.
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