Fractals and implications for mineral favorability maps: the example of iron oxide-copper-gold deposits from Carajás (PA)

Since the concept of fractal geometry was defined in the second half of the twentieth century, the importance of fractals for the description and understanding of geological features has gradually gained importance. More recent work has suggested that the spatial distribution of mineral deposits presents fractal geometry, which represents the complex interaction of geological processes necessary for the genesis of a mineralization. The manifestation of fractal geometry occurs through scale invariance, i.e. the property of a feature that conserves its geometrical characteristics independent of the spatial scale. This property is promising for the study of mineral deposits because it suggests the possibility that information about the geometry of a mineralization at one scale can be used to infer aspects of its geometry at other scales. Since mineralization geometry is a consequence of controls that acted during and after its formation, studies with a fractal approach have theoretical and practical applications. Considering the above, the present research investigated if the geometry of mineral deposits presents scale invariance, and if so, what information it permits to infer about the mineralization controls. For this investigation the study area chosen was the iron oxide-copper-gold (IOCG) Sossego deposit, in the Carajás Mineral Province (PA). IOCG deposits present strong structural control, which taken in conjunction with data availability at the regional, local and microscopic scales make the Sossego deposit area ideal for the proposed research. Thus, data already available in the literature were integrated with new structural measurements and new oriented thin sections of samples collected in the mine pits. Mineralization geometry was evaluated at three different scales: in the regional scale the spatial distribution of the known IOCG deposits was examined; in the local scale the geometry of the mineralized structures and orebodies at the Sossego deposit was examined; in the microscale the geometry of the spatial distribution and the shape of ore mineral grains were evaluated. The bulk of results indicate that the IOCG deposits of Carajás province, and in particular the Sossego deposit, present fractal geometry, conserving the orientation and anisotropy at the different scales. The orientation and anisotropy of the mineralization are geometric aspects that result directly from the control exerted by the underlying structural framework. As a consequence, the results indicate that the structural control generates the scale invariance due to its influence on rock permeability, an essential factor for the genesis of hydrothermal deposits. Permeability is defined at the microscale through foliation planes, microfractures and veinlets, which are directly related to structures of larger scales, such as shear zones, faults and veins, creating a consistent permeable network throughout the scales. In the case of Carajás, the geometry of these permeable areas reflects the interaction between an older ductile framework with diffuse permeability, and a posterior brittle network with focused permeability. The results of this work suggest that the fractal approach to the study of the genesis of mineral deposits has concrete potential to generate relevant results, including for the evaluation of the mineral favorability on exploration areas (AU)