Browsing by Subject "South Kawishiwi Intrusion"
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Item Copper-Nickel Grade Maps for the Spruce Road Deposit, South Kawishiwi Intrusion, Duluth Complex(University of Minnesota Duluth, 2002-02) Peterson, Dean MThis report describes the Cu-Ni mineralization of the Spruce Road area in the northern portion of the South Kawishiwi intrusion. The mineralization in the area is defined by > 9,500 assays from approximately 140,000 feet of core from 232 exploration holes drilled by INCO (220 holes), Bear Creek (6 holes), U.S. Bureau of Mines (3 holes), Hanna Mining (2 holes), and Wallbridge Mining (1 hole). Drilling in the Spruce Road area largely occurred during two time periods: the middle 1950s, following the original discovery of Cu-Ni mineralization, and from 1966 to 1973. Assay data from all of the drill holes within the South Kawishiwi intrusion have been compiled by the author into a comprehensive geological and geochemical database. Drill hole assays for the Spruce Road area have been exported out of this database and form the geochemical basis for this report. Preliminary analysis of the drill hole assay data for all of the deposits of the South Kawishiwi intrusion has led to the identification of two main styles of mineralization associated with the base of the intrusion. These mineralization types include: 1) “Open” – vertically extensive (> 450 meters) mineralization with moderate Cu-Ni grade and low Au+PGE grades. Examples of this open style include the Spruce Road, Serpentine, and Dunka Pit deposits. 2) “Confined” – vertically restricted (< 150 meters) mineralization with high Cu-Ni grades and moderate to very high (locally) Au+PGE grades. Examples of the confined style include the Maturi, Maturi Extension, and the Birch Lake deposits. Regional crosscutting relationships indicate that the “Open” style mineralization preceded the “Confined” style. Moreover, the curvilinear nature of the contact between the styles of mineralization is similar to the regional contacts of most of the intrusions of the Duluth Complex and adds further support to this theory.Item Geology and Cr-PGE Mineralization of the Birch Lake Area, South Kawishiwi Intrusion, Duluth Complex(University of Minnesota Duluth, 1997) Hauck, Steven A; Severson, Mark J; Ripley, Edward M; Goldberg, Steven A; Alapieti, TuomoItem Observations on Cu-Ni Mineralization in the Giants Range Batholith Footwall to the South Kawishiwi Intrusion, Duluth Complex, Northeastern Minnesota(University of Minnesota Duluth, 2003) Hovis, Steven TItem Report on Thin Sections from DDH WM-1, Spruce Road Cu-Ni Deposit, South Kawishiwi Intrusion, Duluth Complex(University of Minnesota Duluth, 2002-04) Sawyer, E. WThe GRB is a large composite, calc-alkaline batholith comprising plutons ranging in composition from diorite, tonalite, granodiorite, quartz monzonite to hornblende syenite. However, two-mica quartz monzonite appears to be the most abundant rock type (Prince and Hanson, 1972; Sims & Viswanathan, 1972). Biotite and hornblende are the two principal ferromagnesian minerals in the batholith, but in some of the more mafic rocks and a few hornblende granites, the hornblendes have cores of clinopyroxene (Sims & Viswanathan, 1972). Some two-mica granites and aplites contain garnet; probably reflecting their very fractionated compositions. Although graywacke and greenstone sequences to the north are contact metamorphed up to the middle amphibolite facies by intrusion of the batholith, petrographic reports of the GRB rocks from west of Babbitt consistently describe primary igneous mineral assemblages. Typically, plagioclase + K-feldspar + quartz + biotite, and either hornblende or muscovite. Commonly described secondary minerals are, chlorite, epidote and muscovite, e.g., Sims & Viswanathan (1972), and this suggests that the original, igneous crystallization mineral assemblages have been partially retrogressed by no more than low grade (maximum of greenschist facies) regional metamorphism. Another commonly reported characteristic of the GRB is that the rocks are foliated, and the textures are variously described as “granulated”, “cataclastic” or “mortar-textured”. Typically, the foliation is subvertical and trends to the SE and, consequently, has been related to the same regional deformation event active in the country rocks at the time of pluton emplacement, or shortly afterwards, since it is generally parallel to the foliation in the older Archaean rocks to the north. In some places this SE-trending foliation in the GRB may have formed in the magmatic or submagmatic state. However, a subvertical, NE-trending foliation in some of the GRB rocks 2 developed after the batholith rocks had crystallized; this foliation is related to faulting at relatively low temperatures. Some of these faults now place batholith rocks directly in contact with older Archaean rocks to the north, cutting out rocks of the contact metamorphic aureole. Green (quoted in Sims and Viswanathan, 1972) reported that rocks of the GRB east of Babbitt are thermally metamorphosed by the Duluth Igneous Complex. Textures there are recrystallized and new mineral assemblages, e.g., hornblende + augite + hypersthene + biotite + magnetite, replace the original igneous mineral assemblages typically found in the GRB farther to the west. Hypersthene has exsolution lamellae, suggesting inversion from pigeonite. Green observed that in some rocks hypersthene was retrograded to biotite + actinolite and that copper sulphides were introduced in some rocks. Green attributed the low variance mineral assemblages east of Babbitt as resulting from partial equilibration between the original igneous assemblage and the amphibolite, hornblende amphibolite or pyroxene-hornfels facies assemblages formed by contact metamorphism. He suggested that thermal metamorphism of the GRB caused by intrusion of the Duluth Igneous Complex reached temperatures of 600 to 675o C, at an assumed pressure of 1 to 2.5 kbars.