Applications and Prospects of Muography in Strategic Deposits

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Detalles Bibliográficos
Publicado en:	Minerals vol. 15, no. 9 (2025), p. 945-985
Autor principal:	Zhou Xingwen
Otros Autores:	Liu, Juntao, Su Baopeng, Yao Kaiqiang, Cai Xinyu, Zhang Rongqing, Li, Ting, Deng Hengliang, Li Jiangkun, Shi, Yan, Liu, Zhiyi
Publicado:	MDPI AG
Materias:	Data acquisition Tomography Mineral exploration Mineral resources Gravity Gas detectors Geophysical data Data integration Localization Overburden Resource exploration Strategic materials Algorithms Cultural heritage Minerals Scientists Data processing Rock masses Data analysis Rocks Cosmic rays Particle physics Geology Muons Monte Carlo simulation National security Occupational safety Imaging Earth science Cosmic radiation Mining accidents & safety Density distribution Metallogenesis Penetration resistance Safety management
Acceso en línea:	Citation/Abstract Full Text + Graphics Full Text - PDF
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Descripción
Resumen:	With strategic mineral exploration extending to deep and complex geological settings, traditional methods increasingly struggle to dissect metallogenic systems and locate ore bodies precisely. This synthesis of current progress in muon imaging (a technology leveraging cosmic ray muons’ high penetration) aims to address these exploration challenges. Muon imaging operates by exploiting the energy attenuation of cosmic ray muons when penetrating earth media. It records muon transmission trajectories via high-precision detector arrays and constructs detailed subsurface density distribution images through advanced 3D inversion algorithms, enabling non-invasive detection of deep ore bodies. This review is organized into four thematic sections: (1) technical principles of muon imaging; (2) practical applications and advantages in ore exploration; (3) current challenges in deployment; (4) optimization strategies and future prospects. In practical applications, muon imaging has demonstrated unique advantages: it penetrates thick overburden and high-resistance rock masses to delineate blind ore bodies, with simultaneous gains in exploration efficiency and cost reduction. Optimized data acquisition and processing further allow it to capture dynamic changes in rock mass structure over hours to days, supporting proactive mine safety management. However, challenges remain, including complex muon event analysis, long data acquisition cycles, and limited distinguishability for low-density-contrast formations. It discusses solutions via multi-source geophysical data integration, optimized acquisition strategies, detector performance improvements, and intelligent data processing algorithms to enhance practicality and reliability. Future advancements in muon imaging are expected to drive breakthroughs in ultra-deep ore-forming system exploration, positioning it as a key force in innovating strategic mineral resource exploration technologies.
ISSN:	2075-163X
DOI:	10.3390/min15090945
Fuente:	ABI/INFORM Global