Paper No. 7
Presentation Time: 3:00 PM
SHRIMP U-PB GEOCHRONOLOGY OF HYDROTHERMAL MONAZITE IN CO-CU-AU ORES OF THE BLACKBIRD DISTRICT, IDAHO
SLACK, John F., U.S. Geol Survey, National Center, MS 954, Reston, VA 20192, ALEINIKOFF, J.N., U.S. Geol Survey, Mail Stop 964, Denver Federal Center, Denver, CO 80225 and FANNING, C. Mark, Research School of Earth Sciences, Australian National Univ, Canberra, ACT 0200, Australia, jfslack@usgs.gov
Recent work has identified previously unknown occurrences of abundant hydrothermal monazite and xenotime in Co-Cu-Au deposits of the Blackbird district, Idaho. The deposits form stratabound and locally stratiform lenses within banded siltite of the Apple Creek Formation, a dominantly siliciclastic metasedimentary sequence of Mesoproterozoic age (ca. 1.45-1.38 Ga). Distinctive biotite±chlorite±garnet rocks commonly enclose the deposits. Cobaltite and chalcopyrite are the major sulfide minerals, accompanied by minor pyrite, arsenopyrite, safflorite, pyrrhotite, bismuthinite, Bi-tellurides, and gold. Gangue minerals consist mainly of quartz with minor biotite, chlorite, muscovite, garnet, tourmaline, apatite, and/or siderite. SEM work shows monazite, xenotime, and allanite in complex intergrowths with cobaltite; monazite commonly surrounds cobaltite and is coeval or younger. Folds, faults, and shear zones deform the deposits; metamorphic grade is middle to upper greenschist facies.
SHRIMP U-Pb dating of 12 monazite grains from the Sunshine deposit yields a 206Pb/238U age of 91±1 Ma. This Late Cretaceous age is similar to those for the oldest phases of the Idaho batholith (ca. 94 Ma), and for metamorphic garnet in northern Idaho (89.6±2.6 Ma; Vervoort et al., 2005). The age for the Blackbird monazite may reflect synsedimentary Mesoproterozoic Co-Cu-Au-REE-Y mineralization followed by pervasive recrystallization of monazite (or formation from precursor allanite+apatite) during Late Cretaceous regional metamorphism. This model requires monazite growth under fluid-rich, upper greenschist-facies conditions, which has been documented in other areas. Alternatively, epigenetic Co-Cu-Au-REE-Y mineralization might have occurred entirely during a Late Cretaceous metamorphic event. This model is problematic, however, because of the generally low LREE/HREE ratios of the ore samples that contrast with the characteristic LREE-rich nature of metamorphogenic REE mineralization elsewhere in the world.