Abstract
The identification of primary geochemical haloes can be used to predict mineral resources in deep-seated orebodies through the delineation of element distributions. The Jiama deposits a typical skarn–porphyry Cu–polymetallic deposit in the Gangdese metallogenic belt of Tibet. The Cu–polymetallic skarn, Cu–Mo hornfels, and Mo ± Cu porphyry mineralization there exhibit superimposed geochemical haloes at depth. Three-dimensional (3D) primary geochemical halo modeling was undertaken for the deposit with the aim of providing geochemical data to describe element distributions in 3D space. An overall geochemical zonation of Zn(Pb) → Au → Cu(Ag) → Mo gained from geochemical cross-sections, together with dip-direction skarn zonation Pb–Zn(Cu) → Cu(Au–Ag–Mo) → Mo(Cu) → Cu–Mo(Au–Ag) and vertical zonation Cu–(Pb–Zn) → Mo–(Cu) → Mo–Cu–(Ag–Au–Pb–Zn) → Mo in the #24 exploration profile, indicates potential mineralization at depth. Integrated geochemical anomalies were extracted by kernel principal component analysis, which has the advantage of accommodating nonlinear data. A maximum-entropy model was constructed for deep mineral resources of uncertainty prediction. Three potential deep mineral targets are proposed on the basis of the obtained geochemical information and background.
Highlights
Primary geochemical halo identification is a key approach for detecting mineral deposits near or below the ground surface [1]
Primary geochemical characteristics of mineral deposits provide important information for predicting deep mineral resources, as they reflect the geochemical processes of metal precipitation and mineral formation
Many methods have been used to identify primary halo characteristics of mineral deposits, including vertical element zonation [3,4,5], element ratios vectoring toward ore zones [6,7,8], Pearce element ratios [1, 9,10,11,12], and alteration indices [13,14,15,16,17,18,19,20,21]
Summary
Primary geochemical halo identification is a key approach for detecting mineral deposits near or below the ground surface [1]. Within the Jiama Cu–polymetallic deposit in Tibet, previous studies focused on element zonation based on lithogeochemical data for surface samples and those from orebodies to build an exploration model for deep mineral resources [22,23,24,25,26,27,28,29]. Primary geochemical zonation and elemental distributions have been proved to be valid methods for estimating mineral resources at Jiama. Three-dimensional (3D) modeling is an efficient approach that has been widely applied in deep mineral exploration [30,31,32,33], with 3D visualizations of primary geochemical haloes directly reflecting the spatial distribution of elements [34, 35]. A 3D model of primary haloes can be useful in geochemical studies of mineral
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