Geochronology of Willyama Supergroup metavolcanics, metasediments and contemporaneous intrusions, Broken Hill, Australia

Stevens, B. P. J.; Page, R. W.; Crooks, Alistair

doi:10.1080/08120090701769456

Cited by 22 publications

(2 citation statements)

References 29 publications

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“…Like El Plomo and other massive sulphide deposits in Colorado, Green Mountain formed in a volcanic arc setting rather than being associated with continental rifting. Although there is uncertainty with the age of sulphide mineralization in Colorado, Pb-Pb isotope ages (Sheridan & Raymond 1984a, 1984b) suggest that sulphide mineralization is older (1.8−1.7 Ga) than BHT deposits in the Diamantina Orogen (Stevens et al 2008). In evaluating the prospectivity of the DGMT for BHT deposits, Zephyr Minerals () proposed that there was base metal zoning along the DGMT with El Plomo prospect showing high grades of Pb, Zn, and Ag in drill holes GC-8 and GC-9.…”

Section: Discussionmentioning

confidence: 99%

The genesis of metamorphosed Paleoproterozoic massive sulphide occurrences in central Colorado: geological, mineralogical and sulphur isotope constraints

Berke,

Spry,

Heimann

et al. 2023

Geol. Mag.

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Paleoproterozoic massive Cu-Zn±Pb±Au±Ag sulphide deposits metamorphosed to the middle-upper amphibolite facies in central-south Colorado formed in a volcanic arc setting on the edge of the Yavapai crustal province. Previously published U-Pb ages on spatially related granitoids range from ∼1.9 to ∼1.1 Ga, while Pb isotope studies on galena from massive sulphides suggest mineralization formed at around 1.8–1.7 Ga. Some deposits in the Dawson-Green Mountain trend (DGMT) and the Gunnison belt are composed of Cu-Zn-Au-(Pb-Ag) mineralization that were overprinted by later Au-(Ag-Cu-Bi-Se-Te) mineralization. Sulphide mineralization is spatially related to amphibolite and bimodal, mafic-felsic volcanic rocks (gabbro, amphibolite, rhyolite and dacite) and granitoids, but it occurs mostly in biotite-garnet-quartz±sillimanite±cordierite schists and gneisses, spatially related to nodular sillimanite rocks, and in some locations, exhalative rocks (iron formations, gahnite-rich rocks and quartz-garnetite). The major metallic minerals of the massive sulphides include chalcopyrite, sphalerite, pyrite, pyrrhotite, and magnetite, with minor galena and gahnite. Altered rocks intimately associated with mineralization primarily consist of various amphiboles (gedrite, tremolite and hornblende), gahnite, biotite, garnet, cordierite, carbonate and rare högbomite. The Zn/Cd ratios of sphalerite (44 to 307) in deposits in the DGMT fall within the range of global volcanogenic massive sulphide (VMS) deposits but overlap with sphalerite from sedimentary exhalative (Sedex) deposits. Sulphur isotope values of sulphides (δ34S = −3.3 to +6.5) suggest sulphur was largely derived from magmatic sources, and that variations in isotopic values resulting from thermochemical sulphate reduction are due to small differences in physicochemical conditions. The preferred genetic model is for the deposits to be bimodal-mafic (Gunnison) to mafic-siliciclastic VMS deposits (Cotopaxi, Cinderella-Bon Ton, DGMT).

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Section: Discussionmentioning

confidence: 99%

The genesis of metamorphosed Paleoproterozoic massive sulphide occurrences in central Colorado: geological, mineralogical and sulphur isotope constraints

Berke,

Spry,

Heimann

et al. 2023

Geol. Mag.

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“…Zircons with ages greater than c. 1400 Ma are likely sourced locally from the Gawler Craton, Barossa Complex and Curnamona Province that collectively record numerous zircon generation events and sedimentary sequences known to contain DZ of these ages (Swain et al 2005; Fanning et al 2007; Barovich & Hand, 2008; Conor & Preiss, 2008; Reid et al 2008; Stevens et al, 2008; Belousova et al 2009; Fraser & Neumann, 2010; Fraser et al 2010; Jagodzinski & Fricke, 2010; Wade, 2011; McAvaney, 2012; Meaney, 2012; Reid & Hand, 2012; Kromkhun et al 2013; Morrissey et al 2013; Reid et al 2014a; Reid et al 2014b; Jagodzinski & McAvaney, 2017; Meaney, 2017; Reid & Payne, 2017; Reid et al 2017; Morrissey et al 2018; Morrissey et al 2019; Reid, Halpin & Dutch, 2019; Jagodzinski et al 2020; Reid et al 2021). The southernmost samples from Sturt Gorge are dominated by c. 1840 Ma zircons, and northward progression through the basin system generally sees a shift in dominance of the c. 1840 Ma population to the younger c. 1590 Ma population of zircon.…”

Section: Discussionmentioning

confidence: 99%

Geochronology and formal stratigraphy of the Sturtian Glaciation in the Adelaide Superbasin

et al. 2023

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The glaciogenic nature of the Yudnamutana Subgroup was first recognized over a century ago, and its global significance was recognized shortly after, with the eventual postulation of a global Sturtian Glaciation and Snowball Earth theory. Much debate on the origin and timing of these rocks, locally and globally, has ensued in the years since. A significant corpus of research on the lithology, sedimentology, geochronology and formal lithostratigraphy of these sequences globally has attempted to resolve many of these debates. In the type area for the Sturtian Glaciation, South Australia’s Adelaide Superbasin, the lithostratigraphy and sedimentology are well understood; however, formal stratigraphic nomenclature has remained complicated and contested. Absolute dates on the stratigraphy are also extremely sparse in this area. The result of these longstanding issues has been disagreement as to whether the sedimentary rocks of the Yudnamutana Subgroup are truly correlative throughout South Australia, and if they were deposited in the same time span recently defined for Sturtian glacial rocks globally, c. 717 Ma to c. 660 Ma. This study presents a large detrital zircon study, summarizes and compiles existing global geochronology for the Sturtian Glaciation and revises the formal lithostratigraphic framework of the Yudnamutana Subgroup. We show equivalence of the rocks that comprise the revised Sturt Formation, the main glaciogenic unit of the Yudnamutana Subgroup, and that it was deposited within the time span globally defined for the Sturtian Glaciation.

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Imposition of a Proterozoic salient on a Palaeozoic orogen at the eastern margin of Gondwana

2009

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Geochronology of Willyama Supergroup metavolcanics, metasediments and contemporaneous intrusions, Broken Hill, Australia

Cited by 22 publications

References 29 publications

The genesis of metamorphosed Paleoproterozoic massive sulphide occurrences in central Colorado: geological, mineralogical and sulphur isotope constraints

The genesis of metamorphosed Paleoproterozoic massive sulphide occurrences in central Colorado: geological, mineralogical and sulphur isotope constraints

Geochronology and formal stratigraphy of the Sturtian Glaciation in the Adelaide Superbasin

Imposition of a Proterozoic salient on a Palaeozoic orogen at the eastern margin of Gondwana

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