Alteration Mineralogy and Stable Isotope Geochemistry of Paleoproterozoic Basement-Hosted Unconformity-Type Uranium Deposits in the Athabasca Basin, Canada

Alexandre, Paul; Kyser, Kurt; Polito, Paul A.; Thomas, Dean

doi:10.2113/gsecongeo.100.8.1547

Cited by 106 publications

(94 citation statements)

References 51 publications

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“…Several studies have now demonstrated that the unconformity-related U deposits are associated with long-lived basement-rooted structures that were likely active during basin-fill, sandstone diagenesis and U mineralisation Alexandre et al 2005Alexandre et al , 2009Polito et al 2005Polito et al , 2006bSouthgate et al 2006;Kyser 2007). In most cases, these structures have been reactivated several times since initial uraninite precipitation as testified by the typically young ages determined for most U deposits in Australia and Canada (Hills & Richards 1976;Gulson & Mizon 1980;Fayek & Kyser 1997;Fayek et al 2000Fayek et al , 2002Kyser et al 2000;Polito et al 2004Polito et al , 2005Alexandre et al 2005Alexandre et al , 2009. Therefore, the conclusion is that elements known to be associated with post-ore alteration may be useful in unconformity-related U exploration because they too indicate formation in a long-lived structure that was originally active when U mineralisation formed.…”

Section: Discussionmentioning

confidence: 99%

“…Petrographic analysis demonstrates that sericite alteration of feldspar occurs first and furthest from the ore zone (Figure 5a), followed by sericite replacement of amphibole and sillimanite and then by increasing amounts of chlorite toward mineralisation ( Figure 5b; Polito et al 2004Polito et al , 2005. Alexandre et al (2005) demonstrated that the formation of crystalline illite/sericite from amphibole and feldspar around the U deposits in the Athabasca Basin created void space due to the minerals' contrasting molar volume. These authors proposed that void space creation promoted additional fluid flow into the basement, with the release of Mg and Fe from minerals such as amphibole, resulting in the precipitation of void-consuming chlorite.…”

Section: Syn-ore Processes In the Large Basement-hosted Uranium Deposmentioning

confidence: 99%

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Advances in understanding the Kombolgie Subgroup and unconformity-related uranium deposits in the Alligator Rivers Uranium Field and how to explore for them using lithogeochemical principles

Polito

Kyser

Alexandre

et al. 2011

Australian Journal of Earth Sciences

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The Alligator Rivers Uranium Field (ARUF) includes the mined and unmined Jabiluka, Ranger, Koongarra and Nabarlek unconformity-related uranium deposits and several small prospects including the newly discovered King River prospect. Uranium mineralisation is hosted by a variety of metamorphosed Nimbuwah Domain lithologies that are unconformably overlain by the Kombolgie Subgroup, a basin package of unmetamorphosed arenites and mafic volcanics. All of the uranium deposits and prospects preserve an identical alteration assemblage that is subdivided into a distal and proximal alteration zone. The distal alteration zone comprises an assemblage of sericite and chlorite that replace albite and amphibole. In some cases, this alteration can be traced 41000 m from the proximal alteration zone that is dominated by uraninite, hematite, chlorite and sericite. Uranium precipitated in the basement as uraninite at 1680 Ma at around 2008C from a fluid having d 18 O fluid values of 3.0+2.8% and dD fluid values of 728+13% VSMOW reflecting an evolved marine source. These geochemical properties are indistinguishable from those recorded by diagenetic illite and chlorite that were collected from the Kombolgie Subgroup sandstones across the ARUF. The illite and chlorite formed in diagenetic aquifers, and where these aquifers intersected favourable basement rocks, such as those containing graphite or other reductants, U was precipitated as uraninite. Therefore, it is proposed that the Kombolgie Subgroup is the source for fluids that formed the deposits. A post-ore alteration assemblage dominated by chlorite, but also comprising quartz+dolomite+sulfide veins cut the uranium mineralisation at all deposits and has historically been recorded as part of the syn-ore mineralisation event. However, these minerals formed anywhere between 1500 to 630 Ma from fluids that have distinctly lower d 18 O fluid values around 1.5% and lower dD fluid values around 745% reflecting a meteoric water origin. Despite unconformity-related uranium deposits having a large alteration halo, they remain difficult to find. The subtle alteration of albite to sericite several hundred metres from mineralisation occurs in isolation of any increase in trace elements such as U and radiogenic Pb and can be difficult or impossible to identify in hand specimen. Whole rock geochemical data indicate that Pearce Element Ratio (PER) analysis and General Element Ratio (GER) analysis may vector into this subtle alteration because it does not rely on an increase in trace elements to identify proximity to ore. PER and GER plots, Al/Ti vs (2Ca þ Na þ K)/Ti, Na/Al vs (Na þ K)/Al, K/Al vs (Na þ K)/Al and (Fe þ Mg)/Al vs (Na þ K)/Al provide a visual guide that readily distinguish unaltered from altered samples. A plot of (Na þ K)/Al and (Fe þ Mg)/Al on the x-axis against the concentration of trace elements on the y-axis reveals that U, Pb, Mo, Cu, B, Br, Ce, Y, Li, Ni, V and Nd are associated with the most intensely altered samples. The lithogeochemical vectors should aid explorers search...

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Section: Discussionmentioning

confidence: 99%

Section: Syn-ore Processes In the Large Basement-hosted Uranium Deposmentioning

confidence: 99%

Advances in understanding the Kombolgie Subgroup and unconformity-related uranium deposits in the Alligator Rivers Uranium Field and how to explore for them using lithogeochemical principles

Polito

Kyser

Alexandre

et al. 2011

Australian Journal of Earth Sciences

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“…Similarly, Kotzer and Kyser (1995) concluded that the brines have a significant meteoric water component and that the high chlorinities were achieved by evaporite dissolution and reaction with feldspars. However, based on comparable isotopic analyses, Alexandre et al (2005) stated that the brines result from mixing between evaporated seawater and low-latitude meteoric waters.…”

Section: Previous Studiesmentioning

confidence: 99%

An evaporated seawater origin for the ore-forming brines in unconformity-related uranium deposits (Athabasca Basin, Canada): Cl/Br and δ37Cl analysis of fluid inclusions

Richard¹,

Banks²,

Mercadier³

et al. 2011

Geochimica et Cosmochimica Acta

105

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“…This difference underlines the variability of possible reductants for the formation of U deposits in sandstone basins (e.g., Kyser 2006, 2012;Yeo and Potter 2010). Ferrous iron has also been suggested as a reductant for unconformity-related U deposits in the Athabasca Basin, but its source is dominantly chlorite, a product of pre-ore clay alteration (Alexandre et al 2005). Other reductants that have been documented elsewhere include, but are not limited to, S (Beverley, South Australia; Wülser et al 2011), graphite or CO (Athabasca Basin deposits; e.g., Cuney and Kyser 2008), organic matter and H 2 S (tabular deposits, Grants U region in USA; Galloway 1980;Saucier 1980), and hydrocarbons in many types of deposits (e.g., Alexandre and Kyser 2006).…”

Section: Implications For the U Metallogeny Of The Otish Basinmentioning

confidence: 99%

Formation of the enigmatic Matoush uranium deposit in the Paleoprotozoic Otish Basin, Quebec, Canada

et al. 2015

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The Matoush uranium deposit is situated in the Paleoproterozoic Otish Basin, northern Quebec, Canada, and is hosted by the Indicator Formation sandstones. Its sheet-like ore bodies are closely associated with the steeply dipping Matoush Fracture, which hosts mafic dykes and minor quartz-feldspar-tourmaline pegmatites. Regional diagenesis, involving oxidizing basinal fluids (δ 2 H ∼−15‰, δ 18 O ∼8‰), produced mostly illite and possibly leached U from accessory phases in the Indicator Formation sandstones. The bimodal Matoush dyke intruded the Indicator Formation along the Matoush Fracture, and the related metasomatism produced Cr-rich dravite and muscovite in both the dyke and the proximal sandstones. Uraninite formed when U 6+ in the basinal brine was reduced to U 4+ in contact with the mafic dyke and by Fe 2+ in Cr-dravite and Cr-muscovite, and precipitated together with eskolaite and hematite. Because of its unique characteristics, the Matoush deposit cannot be easily classified within the generally accepted classification of uranium deposits. Two of its main characteristics (unusual reduction mechanism, structural control) do not correspond to the sandstone-hosted group of deposits (unconformity type, tabular, roll front), in spite of uranium being derived from the Otish Group sandstones.

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Alteration Mineralogy and Stable Isotope Geochemistry of Paleoproterozoic Basement-Hosted Unconformity-Type Uranium Deposits in the Athabasca Basin, Canada

Cited by 106 publications

References 51 publications

Advances in understanding the Kombolgie Subgroup and unconformity-related uranium deposits in the Alligator Rivers Uranium Field and how to explore for them using lithogeochemical principles

Advances in understanding the Kombolgie Subgroup and unconformity-related uranium deposits in the Alligator Rivers Uranium Field and how to explore for them using lithogeochemical principles

An evaporated seawater origin for the ore-forming brines in unconformity-related uranium deposits (Athabasca Basin, Canada): Cl/Br and δ37Cl analysis of fluid inclusions

Formation of the enigmatic Matoush uranium deposit in the Paleoprotozoic Otish Basin, Quebec, Canada

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