Basin architecture and evolution in the Mount Isa mineral province, northern Australia: Constraints from deep seismic reflection profiling and implications for ore genesis

• Published in: Ore geology reviews Vol. 76; pp. 414 - 441
• Main Authors: Gibson, G.M., Meixner, A.J., Withnall, I.W., Korsch, R.J., Hutton, L.J., Jones, L.E.A., Holzschuh, J., Costelloe, R.D., Henson, P.A., Saygin, E.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.07.2016
• Subjects: Basin inversion; Fluid flow; Mount Isa; Pb-Zn Mineralisation; Seismic data; Mount Isa; Pb-Zn Mineralisation; Basin inversion; Fluid flow; Seismic data
• ISSN: 0169-1368; 1872-7360
• DOI: 10.1016/j.oregeorev.2015.07.013

Deep seismic reflection profiling confirms that the Paleo- to Mesoproterozoic Mount Isa mineral province comprises three vertically stacked and partially inverted sedimentary basins preserving a record of intracontinental rifting followed by passive margin formation. Passive margin conditions were established no later than 1655Ma before being interrupted by plate convergence, crustal shortening and basin-wide inversion at 1640Ma in both the 1730–1640Ma Calvert and 1790–1740Ma Leichhardt superbasins. Crustal extension and thinning resumed after 1640 Ma with formation of the 1635–1575Ma Isa Superbasin and continued up to ca. 1615Ma when extensional faulting ceased and a further episode of basin inversion commenced. The 1575Ma Century Pb–Zn ore-body is hosted by syn-inversion sediments deposited during the initial stages of the Isan Orogeny with basin inversion accommodated on east- or northeast-dipping reactivated intrabasinal extensional faults and footwall shortcut thrusts. These structures extend to considerable depths and served as fluid conduits during basin inversion, tapping thick syn-rift sequences of immature siliciclastic sediments floored by bimodal volcanic sequences from which the bulk of metals and mineralising fluids are thought to have been sourced. Basin inversion and fluid expulsion at this stage were entirely submarine consistent with a syn-sedimentary to early diagenetic origin for Pb–Zn mineralisation at, or close to, the seafloor. Farther east, a change from platform carbonates to deeper water continental slope deposits (Kuridala and Soldiers Cap groups) marks the position of the original shelf break along which the north–south-striking Selwyn-Mount Dore structural corridor developed. This corridor served as a locus for strain partitioning, fluid flow and iron oxide–copper–gold mineralisation during and subsequent to the onset of basin inversion and peak metamorphism in the Isan Orogeny at 1585Ma. An episode of post-orogenic strike-slip faulting and hydrothermal alteration associated with the subvertical Cloncurry Fault Zone overprints west- to southwest-dipping shear zones that extend beneath the Cannington Pb–Zn deposit and are antithetic to inverted extensional faults farther west in the same sub-basin. Successive episodes of basin inversion and mineralisation were driven by changes in the external stress field and related plate tectonic environment as evidenced by a corresponding match to bends in the polar wander path for northern Australia. An analogous passive margin setting has been described for Pb–Zn mineralisation in the Paleozoic Selwyn Basin of western Canada. •Mount Isa region underlain by three vertically stacked sedimentary basins•Regional structure dominated by reactivated intrabasinal faults and half-graben•Pb–Zn mineralisation hosted by post-rift and syn-inversion basinal sequences•Pb–Zn and Cu mineralisation tectonically driven during basin inversion