The discovery and geophysical response of the Atlántida Cu–Au porphyry deposit, Chile*
Matthew Hope 1 2 Steve Andersson 11 First Quantum Minerals, Chile, Callao 3164, Las Condes, Santiago 7550000, Región Metropolitana Chile.
2 Corresponding author. Email: matthew.hope@fqml.com
Exploration Geophysics 47(3) 237-247 https://doi.org/10.1071/EG15094
Submitted: 5 September 2015 Accepted: 8 February 2016 Published: 18 March 2016
Abstract
The discovery of the Atlántida Cu–Au–Mo porphyry deposit, which is unconformably overlain by 25–80 m of gravels, is a recent example of exploration success under cover in a traditional mining jurisdiction. Early acquisition of geophysics was a key tool in the discovery, and in later guiding further exploration drilling throughout the life of the project. Detailed review of the geophysical response of the deposit, with respect to the distribution of lithologies and alteration, coupled with their petrophysical properties has allowed full characterisation, despite no exposure at the surface of host rock nor porphyry-style mineralisation. Data acquired over the project include induced polarisation, magnetotellurics, ground and airborne magnetics, ground-based gravimetry, and petrophysical sampling.
The distribution of the key geological features of the deposit has been inferred via acquisition of petrophysical properties and interpretation of surface geophysical datasets. Magnetic susceptibility is influenced strongly by both alteration and primary lithology, whilst density variations are dominated by primary lithological control. Several studies have shown that electrical properties may map the footprint of the hydrothermal system and associated mineralisation, via a combination of chargeability and resistivity. These properties are observed in geophysical datasets acquired at surface and allow further targeting and sterilisation at the deposit and project scale.
By understanding these geophysical characteristics in a geological context, these data can be used to infer distribution of lithological units, depth to exploration targets and the potential for high grade mineralisation. Future exploration will likely be increasingly reliant on the understanding of the surface manifestations of buried deposits in remotely acquired data. This review summarises the application and results of these principles at the Atlántida project of northern Chile. Geophysical data can be used to improve the chances of discovery beneath post-mineral cover, and also improve drilling results throughout the advanced exploration of the program. The process of data review against geological control information is essential.
Key words: Atlántida, discovery, petrophysics, porphyry.
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