UNSUPERVISED DELINEATION OF PROSPECTIVITY ZONES FOR STRATIFORM CU-CO IN THE SOUTHERN COPPERBELT MARGIN (ZAMBIA)
https://doi.org/10.55452/1998-6688-2026-23-2-435-450
Abstract
This study presents an unsupervised workflow for delineating prospectivity zones for stratiform copper-cobalt mineralization in the southern margin of the Central African Copperbelt, Zambia, using only airborne geophysical data (gravity, magnetics, radiometry, terrain). Three clustering algorithms-K-Means, Fuzzy C-Means (FCM), and Self-Organizing Maps (SOM)-were applied, followed by consensus clustering to isolate robust target zones. Key geophysical filters (tilt derivative, total horizontal derivative, analytic signal) and radiometric ratios (U/Th, U/K) were computed and compared across clusters. The most prospective cluster was validated against literature-calibrated geophysical thresholds and was found to match known exploration criteria and regional structural trends. A final probabilistic prospectivity map was generated from FCM membership, classifying targets into three confidence levels. While lack of drill-hole data prevents quantitative accuracy assessment, this approach demonstrates that fully unlabeled machine learning on airborne data can effectively guide early-stage exploration in data-sparse regions. The proposed workflow offers a reproducible framework for AI-driven prospectivity mapping in frontier terrains.
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Review
For citations:
Saduov A. UNSUPERVISED DELINEATION OF PROSPECTIVITY ZONES FOR STRATIFORM CU-CO IN THE SOUTHERN COPPERBELT MARGIN (ZAMBIA). Herald of the Kazakh-British Technical University. 2026;23(2):435-450. (In Kazakh) https://doi.org/10.55452/1998-6688-2026-23-2-435-450
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