Curvature Attribute from Surface-Restoration as Predictor Variable in Kupferschiefer Copper Potentials
Pablo Mejía-Herrera and Jean-Jacques Royer and Guillaume Caumon and Alain Cheilletz. ( 2015 )
in: Natural Resources Research, 24:3
Abstract
This work explains a procedure to predict Cu potentials in the ore-Kupferschiefer using structural surface-restoration and logistic regression (LR) analysis. The predictor in the assessments are established from the restored horizon that contains the ore-series. Applying flexural-slip to unfold/unfault the 3D model of the Fore-Sudetic Monocline, we obtained curvature for each restored time. We found that curvature represents one of the main structural features related to the Cu mineralization. Maximum curvature corresponds to high internal deformation in the restored layers, evidencing faulting and damaged areas in the 3D model. Thus, curvature may highlight fault systems that drove fluid circulation from the basement and host the early mineralization stages. In the Cu potential modeling, curvature, distance to the Fore-Sudetic Block and depth of restored Zechstein at Cretaceous time are used as predictors and proven Cu-potential areas as targets. Then, we applied LR analysis establishing the separating function between mineralized and non-mineralized locations. The LR models show positive correspondence between predicted probabilities of Cu-potentials and curvature estimated on the surface depicting the mineralized layer. Nevertheless, predicted probabilities are particularly higher using curvatures obtained from Late Paleozoic and Late Triassic restorations.
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BibTeX Reference
@article{mejiaherrera:hal-01304796, abstract = {This work explains a procedure to predict Cu potentials in the ore-Kupferschiefer using structural surface-restoration and logistic regression (LR) analysis. The predictor in the assessments are established from the restored horizon that contains the ore-series. Applying flexural-slip to unfold/unfault the 3D model of the Fore-Sudetic Monocline, we obtained curvature for each restored time. We found that curvature represents one of the main structural features related to the Cu mineralization. Maximum curvature corresponds to high internal deformation in the restored layers, evidencing faulting and damaged areas in the 3D model. Thus, curvature may highlight fault systems that drove fluid circulation from the basement and host the early mineralization stages. In the Cu potential modeling, curvature, distance to the Fore-Sudetic Block and depth of restored Zechstein at Cretaceous time are used as predictors and proven Cu-potential areas as targets. Then, we applied LR analysis establishing the separating function between mineralized and non-mineralized locations. The LR models show positive correspondence between predicted probabilities of Cu-potentials and curvature estimated on the surface depicting the mineralized layer. Nevertheless, predicted probabilities are particularly higher using curvatures obtained from Late Paleozoic and Late Triassic restorations.}, author = {Mej{\'i}a-Herrera, Pablo and Royer, Jean-Jacques and Caumon, Guillaume and Cheilletz, Alain}, doi = {10.1007/s11053-014-9247-7}, hal_id = {hal-01304796}, hal_version = {v1}, journal = {{Natural Resources Research}}, keywords = {Structural restoration ; Fault system ; Fault activity ; Logistic regression ; Predictive modeling}, month = {September}, number = {3}, publisher = {{Springer Verlag}}, title = {{Curvature Attribute from Surface-Restoration as Predictor Variable in Kupferschiefer Copper Potentials}}, url = {https://hal.univ-lorraine.fr/hal-01304796}, volume = {24}, year = {2015} }