Copper‐gold mineralisation in New Guinea: Numerical modelling of collision,fluid flow and intrusion‐related hydrothermal systems |
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Authors: | P A Gow P Upton C Zhao K C Hill |
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Institution: | 1. Australian Geodynamics Cooperative Research Centre , CSIRO Exploration and Mining , PO Box 437, Nedlands, WA, 6009, Australia;2. MIM Exploration Pty Ltd , Locked Mailbag 100, Mt Isa, Qld, 4825, Australia;3. Department of Geological Sciences , University of Maine , Orono, ME, 04469, USA;4. Australian Geodynamics Cooperative Research Centre , CSIRO Exploration and Mining , PO Box 437, Nedlands, WA, 6009, Australia;5. Australian Geodynamics Cooperative Research Centre, Earth Sciences , La Trobe University , Vic., 3083, Australia;6. 3D-GEO, Earth Sciences , University of Melbourne , Vic., 3010, Australia |
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Abstract: | Two‐ and three‐dimensional numerical modelling techniques, constrained by key geodynamic data, provide insights into the controls on development of porphyry‐related Cu–Au mineralisation in the Tertiary collision zone of New Guinea. Modelling shows that the creation of local dilation to facilitate magma emplacement can be caused by reactivation of arc‐normal transfer faults, where they cut the weakened fold belt. Additionally, dilation occurs where fluid overpressuring is caused by collision‐related, south‐directed fluid flow being localised into the more permeable units of the Mesozoic passive‐margin sedimentary succession. Rapid uplift and erosion, which may be a mechanism for magmatic fluid release in these systems, is shown to be greatest in the west of West Papua, where the stronger Australian crust acts as a buttress. Within the Papuan Fold Belt, uplift is greatest near the margins, where the weaker fold belt abuts the stronger crust and/or major faults have been reactivated. Increased orographically induced precipitation and erosion exposes the lower parts of the stratigraphy within or on the margins of these uplifted zones. On a smaller scale, 2–D coupled fluid‐flow ‐ thermal‐chemical modelling uses a scenario of fluid mixing to calculate metal precipitation distribution and magnitude around an individual intrusive complex. Modelling highlights the interdependence of the spatial permeability structure, the regional temperature gradient, and the geometry of the convection cells and how this impacts on the distribution of metal precipitation. |
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Keywords: | collisional zone New Guinea numerical modelling porphyry‐copper deposits |
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