Nicholas H.S. Oliver scite author profile

Comparison of mass transfer patterns, geometry and microstructures developed within and around veins allows the interpretation of processes of fluid flow during deformation, metamorphism and mineralization. A classification of vein types based on the degree of interaction with wallrock (using petrological, geochemical or isotopic indicators) can be used to identify a range of processes, from closed system behaviour in which the vein mass is derived from local wallrock, through to open system behaviour in which the vein mass is derived externally. Microstructural characteristics, such as wallrock selvages, multiple growth events recorded by vein seams and vein crystal morphology, also help to constrain mass transfer patterns during vein formation. We present a range of processes for vein formation, including: (i) the formation of closed system fibrous veins by dissolution–precipitation creep, including varieties in which tensile failure is not required; (ii) pressure‐ or kinetically dependent closed system segregation veins in which transfer of soluble components from wallrock to vein leaves behind a residual selvage; (iii) similar vein–selvage patterning, but with mass imbalances between vein and wallrock requiring fluid advection through both interconnected fracture networks and in the surrounding permeable rock; and (iv) the proposed formation of veins by fluid ascent in mobile hydrofractures, in which isotopic or chemical disequilibrium within and around the vein suggests that the crack and fluid within it moved essentially as one. The postulate of rapid fluid and mass transfer via such mobile hydrofractures has implications for the release of volatiles from metamorphic terrains. Also, consideration of a broad range of possible vein‐forming mechanisms is highly desirable when dealing with mineral deposits found in deformed, metamorphosed rocks, because closed system veining may produce patterns that, if erroneously recognized as being open systems, could lead to false interpretations of the role of tectonic fracturing in ore genesis.

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Iron Oxide Copper-Gold Deposits<subtitle>Geology, Space-Time Distribution, and Possible Modes of Origin</subtitle>

Williams¹,

Barton²,

Johnson³

et al. 2005

270

127

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Geodynamic evolution of the Proterozoic Mount Isa terrain

O'Dea¹,

Lister²,

MacCready³

et al. 1997

100

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The stable isotope signature of kilometre‐scale fracturedominated metamorphic fluid pathways, Mary Kathleen, Australia

Oliver

Cartwright

Wall

et al. 1993

Journal Metamorphic Geology

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Large calcite veins and pods in the Proterozoic Corella Formation of the Mount Isa Inlier provide evidence for kilometre-scale fluid transport during amphibolite facies metamorphism. These 11% to lWm-scale podiform veins and their surrounding alteration zones have similar oxygen and carbon isotopic ratios throughout the 200 x 10-km Mary Kathleen Fold Belt, despite the isotopic heterogeneity of the surrounding wallrocks. The fluids that formed the pods and veins were not in isotopic equilibrium with the immediately adjacent rocks. The pods have S13Cakirc values of -2 to -7%. and 6180ulfilc values of 10.5 to 12.5%. Away from the pods, metadolerite wallrocks have 6180whorc-mck values of 3.5 to 7%., and unaltered banded calc-silicate and marble wallrocks have S"C,,,, of -1.6 to -0.6% and ,5180w,e of 18 to 21%. In the alteration zones adjacent to the pods, the 6l8O values of both metadolerite and calc-silicate rocks approach those of the pods. Large calcite pods hosted entirely in calc-silicates show little difference in isotopic composition from pods hosted entirely in metadolerite. Thus, 100-to 500-m-scale isotopic exchange with the surrounding metadolerites and calc-silicates does not explain the observation that the 6"O values of the pods are intermediate between these two rock types. Pods hosted in felsic metavolcanics and metasiltstones are also isotopically indistinguishable from those hosted in the dominant metadolerites and calc-silicates. These data suggest the veins are the product of infiltration of isotopically homogeneous fluids that were not derived from within the Corella Formation at the presently exposed crustal level, although some of the spread in the data may be due to a relatively small contribution from devolatilization reactions in the calc-silicates, or thermal fluctuations attending deformation and metamorphism. The overall L-shaped trend of the data on plots of 6I3C vs. 6I80 is most consistent with mixing of large volumes of externally derived fluids with small volumes of locally derived fluid produced by devolatilization of calc-silicate rocks. Localization of the vein systems in dilatant sites around metadolerite/calc-silicate boundaries indicates a strong structural control on fluid flow, and the stable isotope data suggest fluid migration must have occurred at scales greater than at least 1 km. The ultimate source for the external fluid is uncertain, but is probably fluid released from crystallizing melts derived from the lower crust or upper mantle. Intrusion of magmas below the exposed crustal level would also explain the high geothermal gradient calculated for the regional metamorphism.

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100th Anniversary Special Paper: Numerical Models of Extensional Deformation, Heat Transfer, and Fluid Flow across Basement-Cover Interfaces during Basin-Related Mineralization

Oliver¹,

McLellan²,

Hobbs³

et al. 2006

Economic Geology

121

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Hydrothermal history of the Mary Kathleen Fold Belt, Mt Isa Block, Queensland

Oliver

1995

Australian Journal of Earth Sciences

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Synorogenic hydrothermal origin for giant Hamersley iron oxide ore bodies

Powell

Oliver

et al. 1999

Geol

132

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Element redistribution and mobility during upper crustal metamorphism of metasedimentary rocks: an example from the eastern Mount Lofty Ranges, South Australia

Hammerli

Spandler

Oliver

2016

Contrib Mineral Petrol

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