2007 GSA Denver Annual Meeting (28–31 October 2007)

Paper No. 2
Presentation Time: 8:15 AM

HYDROTHERMAL METAMORPHISM AND TRANSIENT DEPTH FLUCTUATIONS OF THE BRITTLE-DUCTILE TRANSITION DURING SHEAR-ZONE HOSTED IOCG MINERALIZATION


NELSON, Eric P., Geology and Geological Engineering, Colorado School of Mines, 1500 Illinois St, Golden, CO 80401, HITZMAN, Murray W., Chair, National Research Council Committ on Induced Seismicity Potential and Dept. Geology & Geological Engineering, Colorado School of Mines, Golden, CO 80401 and MONTEIRO, Lena V.S., Instituto de Geociências, Universidade Estadual de Campinas, Campinas, Sao Paulo, Brazil, enelson@mines.edu

In the Carajás province of northern Brazil Fe-oxide-Au-Cu (IOCG) style ore deposits (e.g., Sossego-Sequeirinho, Salobo, Igarapé Bahia, Alemão) are hosted in shear zones with both brittle and ductile deformation and hydrothermal metamorphic assemblages different from the surrounding wallrocks (greenschist grade Archean meta-sedimentary and meta-volcanic rocks with local gabbroic to granitic intrusions). In contrast, shear zones contain hydrothermal metamorphic assemblages including early sodic (albite-scapolite) or calcic-sodic (actinolite-apatite) assemblages and later potassic and calcic assemblages including K-feldspar, biotite, grunerite, magnetite, and in higher temperature zones fayalite, garnet, and sillimanite. Structural features in the shear zones include mylonitic foliation in the hydrothermal metamorphic assemblage, open-space fill veins and breccia with foliated clasts and a chalcopyrite-rich hydrothermal matrix associated with potassic and calcic assemblages, and mylonitic foliation with strongly deformed sulfides.

A model to explain these features suggests that the shear zones developed in the crustal brittle-ductile transition zone defined thermally by greenschist metamorphic grade in the wallrocks (~10-15 km depth). However, in the shear zones the brittle-ductile transition was elevated, possibly due to shear heating and microscopic advective fluid flow. Shear zone strain features suggest that inter-seismic displacement by ductile flow oscillated with seismic displacement by brittle fracturing and hydrothermal fluid flow. Pre-mineralization calcic-potassic hydrothermal metamorphism occurred during inter-seismic phases with fluid-pressure build-up. Sulfide ore-mineral precipitation occurred during high-strain rate seismic phases with fluid pressure release brecciation. Post-seismic ductile flow displacement then mylonitized ore-phase sulfide minerals. The brittle-ductile transition during the seismic ore precipitation phase is defined by high-fluid pressure (lower mean stress) and high strain rate and was transiently elevated only within the shear zone; the brittle-ductile transition as defined by thermally-activated crystal plasticity remained regionally sub-horizontal outside the shear zone.