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Hardrock Seismic Attribute Analysis and AVO modeling for Carlin-type Deposit Exploration Kyle T. Gray1 Jared Townsend2 John Louie1 Great Basin and Western Cordillera Mining Geophysics Symposium 11/23/2013 1 University of Nevada, Reno Seismological Laboratory 2 Barrick Gold Corporation Overview • Both petroleum and mineral exploration attempt to locate zones of increased porosity • The CTD environment shares similarities with carbonate oil and gas reservoirs, which allows for adoption of oil and gas methodologies • We cannot get all of the benefits of seismic data without abundant wire-line logs Seismic Interpretation Methods 1. Conventional interpretation – Manual picking of horizons and faults 2. Seismic attributes – Analogous to filtering of potential fields data 3. Forward modeling – Synthetic data from wire-line logs 4. Inversion – Incorporation of wire-line logs to invert seismic data into elastic properties Petrophysical studies important in every step Hardrock Seismic • Structural complexity • Crystalline environment – or close spatial association with magmatism • Heterogeneous regolith zone • High ambient noise – Haul trucks, mining operations • Variable source- receiver couplings • Ground relief PREVIOUS HARDROCK SEISMIC STUDIES Seismic in Mining Bushveld, South Africa Witwatersrand, South Africa Flin Flon, Quebec Mount Morgan, Australia • Previous seismic data for mining exploration is largely collected in the Proterozoic setting – No carbonates – No extant porosity – No direct analogies to petroleum industry Bell Allard, Quebec Manitouwadge, Ontario St. Ives, Australia Mt. Isa, Australia Kristienberg, Sweden Pyhasalmi, Finland Half Mile Lake, Canada Voisey’s Bay, Labrador, Canada (Harrison and Urosevic, 2012) CTD Formation • Ore genesis relates to structural and magmatic overprint on the platformslope environment (Cook and Corboy, 2004) Carlin Type Deposit paleo-stratigraphic setting: carbonate platform-slope http://www.beg.utexas.edu/lmod/_IOL-CM03/cm03-step01.htm Seismic response in carbonate ) platform-slope environment (Jansen et. al, 2011 Alteration and Petrophysics • Decarbonatization = decreased seismic parameters and increased porosity. • Sample bias in drill-core petrophysics towards less altered rock. Acoustic Impedance Vs. Porosity (Wenban Subset) 20 Decarbonitized Porosity (%) 15 No Decarbonitization No DECAL, ARGIL, SILIC R² = 0.4867 10 5 R² = 0.0026 0 0 -5 2000 4000 6000 8000 10000 12000 14000 Acoustic Impedance 16000 18000 20000 Wire-line Logs Tertiary Limestone Decarb. Intensity from geolog 3700 m/s 5700 m/s Pseudo wire-line log • Drill core sampled at high resolution • Cannot sample heavily altered rock • Stresses importance of wire-line logging 150-250 ft Case Study 1300 ft Seismic Attributes - potential field analogy RTP Magnetics Total Horizontal Gradient Average frequency Instantaneous amplitude Intro to Pre-stack Data Stacked trace Increasing offset Sum all offsets http://subsurfwiki.org/wiki/Gather Amplitude Versus Offset (AVO) Model • Far offset anomaly at base of decarbonatization Gradient plot for base of decarbonatization Amplitude Offset Offset Pre-stack Migrated Gathers offset offset offset … Inversion • Pre-stack inversion using ONE wire-line log Tuff in geolog 2.6 g/cc 2.15 g/cc Conclusions • Decarbonatization produces distinct rock property contrasts but more wire-line data is needed to fully understand the system. • Seismic attributes calculated in CTD environment can help reveal alteration features • Inversion shows promise given that the case study only used one wire-line log. References • Salisbury, M., Harvey, C., Matthews, L., The acoustic properties of ores and host rocks in hardrock terranes In: D. Eaton, B. Milkereit & M. Salisbury, eds. Hardrock Seismic Exploration. Tulsa: Society of Exploration Geophyiscs, p. 141. • Harrison, C. B. & Urosevic, M., 2012. Seismic processing, inversion, and AVO for gold exploration - Case study from Western Australia. Geophysics, 77(5), p. 235-243. • Cook, H. & Corboy, J., 2004. Great Basin Paleozoic Carbonate Platform: Facies, Facies Transitions, Depositional Models, Platform Architecture, Sequence Stratigraphy, And Predictive Mineral Host Models, Field Trip Guidebook—Metallogeny of the Great Basin Project, August 17—22, 2003 :U.S. Geological Survey Open-File Report 2004-1078. • Janson, X., Kerans, C., Loucks, R. Marhx, M., Reyes, C., Murguia, F., 2001, AAPG Bulletin, v. 95, No. 1 (January 2001) p. 105-146
