Magmatic sulphides in high-K calc-alkaline to shoshonitic and alkaline rocks

We investigate in both mineralised and barren systems the occurrence and chemistry of magmatic sulphides and their chalcophile metal cargo behaviour during evolution of compositionally different magmas in diverse geodynamic settings. The investigated areas are: (a) the Miocene Konya magmatic province (hosting the Doganbey Cu-Mo and Inlice Au-epithermal deposits) (Post-Subduction) and (b) the Miocene Usak basin (Elmadag, Itecektepe and Beydagi volcanoes, the latter associated with the Kisladag Au porphyry) in Western Turkey (Post-Subduction). For comparison we also investigate (c) the barren Plio-Quaternary Kula volcanic field, west of Usak (Intraplate) and finally we discuss and compare all the above areas with the already studied (d) Quaternary Ecuadorian volcanic arc (host to the Miocene Llurimagua Cu-Mo and Cascabel Cu-Au porphyry deposits) (Subduction). The volcanism of the studied areas displays a wide range of SiO2 spanning from basalts to andesites/dacites and from high K-calc-alkaline to shoshonitic series. Multiphase magmatic sulphides occur in different amounts in all investigated areas and based on textural and compositional differences, they can be classified in different types, which crystallised at different times (early versus late saturation). A decrease in the sulphide Ni/Cu (proxy for mss-monosulphide solid solution/iss-intermediate solid solution) ratio is noted with magmatic evolution. Starting with an early stage, saturating Ni-richer/Cu-poorer sulphides hosted by early crystallising minerals e.g. olivine/pyroxene, leading up to a later stage, producing Cu-richer sulphides hosted by magnetite. The most common sulphide type resulting from an early saturating stage is composed of a Cu-poor/Ni-rich (pyrrhotite/mss) and one/two Cu-rich (cubanite, chalcopyrite/iss) phases making up 84 and 16 area % of the sulphide, respectively. Our results suggest that independently of the magma composition, geodynamic setting and whether or not the system has generated an ore deposit on the surface, sulphide saturation occurred in variable degrees in all studied areas and magmatic systems and is characterised by a similar initial metal content of the magmas. However not all studied areas present all sulphide types and the sulphide composition is dependent on the nature of the host mineral. In particular sulphides, resulting from the late stage, consisting of Cu-rich phases (chalcopyrite ,bornite, digenite/iss) are hosted exclusively by magnetite and are found only in magmatic provinces associated with porphyry Cu (Konya and Ecuador) and porphyry Au (Beydagi) deposits.

PRECIOUS METALS IN THE MORRISON DEPOSIT, SUDBURY, CANADA

The Morrison deposit, located in Sudbury Mining Camp, produces ore containing copper, nickel, platinum, palladium and gold. Chalcopyrite dominates the mineral assemblage, while the main Ni-bearing phases are pentlandite and millerite. Cubanite, mackinawite, pyrrhotite, magnetite, sphalerite and galena are present too. Bornite is the main mineral in the peripheral parts of veins, often containing native silver veinlets. Platinum occurs as discrete PGM minerals: composite grains of moncheite (PtTe2) with hessite (Ag2Te); maslovite (PtBiTe) and sperrylite (PtAs2) are rare. Palladium can occur as a substitution in pentlandite and as discrete PGM minerals: michenerite (PdBiTe) and paolovite (Pd2Sn). Tellurides and bismuth-tellurides often display Pt-Pd and Bi-Te substitutions. Gold is present as a native element and as electrum. A zonation in the occurrence of elements can be explained by fractional crystallization of magmatic sulphides. There is a possibility of partial remobilization of precious metals (especially gold and palladium) by later hydrothermal and/or metamorphic processes with associated authigenic quartz, silicates (epidote, amphiboles) and secondary magnetite containing sulphide inclusions.