New radiogenic (40Ar/39Ar) and stable (oxygen, hydrogen, and sulfur) isotope analyses of metamorphic and metasomatic minerals constrain the age, metasomatic evolution, and genesis of the Eloise Cu-Au deposit (3.1 Mt @ 5.5% Cu, 1.4 g/t Au, and 16 g/t Ag). Biotite from a pre- to syn-D-2-stage vein has an 40Ar/39Ar age of 1555 +/- 4 Ma which is interpreted to coincide with a regional metamorphic event synchronous with D-2. Six later stages of, alteration and mineralization are recognized, all of which postdate peak metamorphism and D-2. Stages I to III are volumetrically the most significant and comprise early albitization (stage I), quartz-homblende-biotite veins and alteration (stage II), and Cu-Au mineralization (stage III). Stages IV, V, and VI are localized vein events and postdate the main Cu-Au mineralization. Stage II vein and alteration hornblendes have 40Ar/39Ar ages of 1530 +/- 3 Ma. Biotite from the same stage has an 40Ar/39Ar age of 1521 +/- 3 Ma. Muscovite from a postore shear zone has an (40)A/39Ar age of 1514 +/- 3 Ma. These results provide a maximum (ca. 1530 Ma) and minimum (ca. 1514 Ma) age for the mineralizing event. However, the intimate relationship between stage II mafic-silicate veins and alteration and the stage III Cu-Au event combined with fluid inclusion results which indicate that a cooling, evolving high salinity fluid was responsible for both stages suggests that the older age is likely to be closer to the age of mineralization. The stage II biotite age of ea. 1521 Ma is interpreted to record thermal resetting during postore ductile deformation. The results suggest that micas in the Cloncurry district are more susceptible to later thermal resetting than amphiboles which may have significant implications for de posits which have only been dated by micas. Quartz from stages II, III, and IV have delta O-18(quartz) values ranging between 10.1 and 11.9 per mil. Stage II biotite has a lower delta O-18 composition (5.6 parts per thousand) than biotite from a pre-D-2 vein (6.9 parts per thousand), but both have identical deltaD compositions (-84 parts per thousand). Stage II hornblende has lower delta O-18 (6.8 and 7.4 parts per thousand) and deltaD (-88 and -90 parts per thousand) values than does stage III actinolite (8.0 and -84 parts per thousand, respectively). The delta S-34 values for chalcopyrite, pyrrhotite, and pyrite fall in a narrow range between 0.0 and 2.3 per mil. A distinct trend can be recognized with delta S-34 values becoming progressively greater from south to north, thus reflecting the zoned alteration system (magnetite-pyrite-rich in the south through to pyrrhotite rich in the north). The change in mineralogy and sulfur isotope values may be due to cooling and sulfidation processes which resulted in changes in oxygen and sulfur fugacities. The oxygen, hydrogen, and sulfur isotope data, combined with high-temperature and high-salinity fluid inclusion data, indicate a predominantly magmatic origin for the ore forming fluids. The deposit is interpreted to have formed from magmatic hydrothermal fluids which were tapped by deep-seated crustal structures. New radiogenic (40Ar/39Ar) and stable (oxygen, hydrogen, and sulfur) isotope analyses of metamorphic and metasomatic minerals constrain the age, metasomatic evolution, and genesis of the Eloise Cu-Au deposit (3.1 Mt @ 5.5% Cu, 1.4 g/t Au, and 16 g/t Ag). Biotite from a pre- to syn-D-2-stage vein has an 40Ar/39Ar age of 1555 +/- 4 Ma which is interpreted to coincide with a regional metamorphic event synchronous with D-2. Six later stages of, alteration and mineralization are recognized, all of which postdate peak metamorphism and D-2. Stages I to III are volumetrically the most significant and comprise early albitization (stage I), quartz-homblende-biotite veins and alteration (stage II), and Cu-Au mineralization (stage III). Stages IV, V, and VI are localized vein events and postdate the main Cu-Au mineralization. Stage II vein and alteration hornblendes have 40Ar/39Ar ages of 1530 +/- 3 Ma. Biotite from the same stage has an 40Ar/39Ar age of 1521 +/- 3 Ma. Muscovite from a postore shear zone has an (40)A/39Ar age of 1514 +/- 3 Ma. These results provide a maximum (ca. 1530 Ma) and minimum (ca. 1514 Ma) age for the mineralizing event. However, the intimate relationship between stage II mafic-silicate veins and alteration and the stage III Cu-Au event combined with fluid inclusion results which indicate that a cooling, evolving high salinity fluid was responsible for both stages suggests that the older age is likely to be closer to the age of mineralization. The stage II biotite age of ea. 1521 Ma is interpreted to record thermal resetting during postore ductile deformation. The results suggest that micas in the Cloncurry district are more susceptible to later thermal resetting than amphiboles which may have significant implications for de posits which have only been dated by micas. Quartz from stages II, III, and IV have delta O-18(quartz) values ranging between 10.1 and 11.9 per mil. Stage II biotite has a lower delta O-18 composition (5.6 parts per thousand) than biotite from a pre-D-2 vein (6.9 parts per thousand), but both have identical deltaD compositions (-84 parts per thousand). Stage II hornblende has lower delta O-18 (6.8 and 7.4 parts per thousand) and deltaD (-88 and -90 parts per thousand) values than does stage III actinolite (8.0 and -84 parts per thousand, respectively). The delta S-34 values for chalcopyrite, pyrrhotite, and pyrite fall in a narrow range between 0.0 and 2.3 per mil. A distinct trend can be recognized with delta S-34 values becoming progressively greater from south to north, thus reflecting the zoned alteration system (magnetite-pyrite-rich in the south through to pyrrhotite rich in the north). The change in mineralogy and sulfur isotope values may be due to cooling and sulfidation processes which resulted in changes in oxygen and sulfur fugacities. The oxygen, hydrogen, and sulfur isotope data, combined with high-temperature and high-salinity fluid inclusion data, indicate a predominantly magmatic origin for the ore forming fluids. The deposit is interpreted to have formed from magmatic hydrothermal fluids which were tapped by deep-seated crustal structures.
