Staged formation of the supergiant Olympic Dam uranium deposit, Australia-Reference-Cited by-同舟云学术

Staged formation of the supergiant Olympic Dam uranium deposit, Australia

Published:2021-07-15 Issue:11 Volume:49 Page:1312-1316
ISSN:0091-7613
Container-title:Geology
language:en
Short-container-title:

Author:

Ehrig Kathy¹²,Kamenetsky Vadim S.²,McPhie Jocelyn²,Macmillan Edeltraud¹,Thompson Jay²,Kamenetsky Maya²,Maas Roland³

Affiliation:

1. BHP Olympic Dam, Adelaide, SA 5000, Australia

2. School of Natural Sciences, University of Tasmania, Hobart, TAS 7001, Australia

3. School of Earth Sciences, University of Melbourne, Melbourne, VIC 3010, Australia

Abstract

Abstract The origins of many supergiant ore deposits remain unresolved because the factors responsible for such extreme metal enrichments are not understood. One factor of critical importance is the timing of mineralization. However, timing information is commonly confounded by the difficulty of dating ore minerals. The world's largest uranium resource at Olympic Dam, South Australia, is exceptional because the high abundance of U allows U-Pb dating of ore minerals. The Olympic Dam U(-Cu-Au-Ag) ore deposit is hosted in ca. 1.59 Ga rocks, and the consensus has been that the supergiant deposit formed at the same time. We argue that, in fact, two stages of mineralization were involved. Paired in situ U-Pb and trace element analyses of texturally distinct uraninite populations show that the supergiant size and highest-U-grade zones are the result of U addition at 0.7–0.5 Ga, at least one billion years after initial formation. This conclusion is supported by a remarkable clustering of thousands of radiogenic 207Pb/206Pb model ages of Cu sulfide grains at this time. Upgrading of the original ca. 1.59 Ga U deposit to its present size at 0.7–0.5 Ga may have resulted from perturbation of regional fluid flow triggered by global climatic (deglaciation) and tectonic (breakup of Rodinia) events.

Publisher

Geological Society of America

Subject

Geology

Link

http://pubs.geoscienceworld.org/gsa/geology/article-pdf/49/11/1312/5435640/g48930.1.pdf

Reference35 articles.

1. Evolution and architecture of a large felsic Igneous Province in western Laurentia: The 1.6 Ga Gawler Range Volcanics, South Australia;Allen;Journal of Volcanology and Geothermal Research,2008

2. Early, deep magnetite-fluorapatite mineralization at the Olympic Dam Cu-U-Au-Ag deposit, South Australia;Apukhtina;Economic Geology and the Bulletin of the Society of Economic Geologists,2017

3. Carbonates at the supergiant Olympic Dam Cu-U-Au-Ag deposit, South Australia. Part 1: Distribution, textures, associations and stable isotope (C, O) signatures;Apukhtina;Ore Geology Reviews,2020

4. BHP, 2020, Annual Report 2020: https://www.bhp.com/-/media/documents/investors/annual-reports/2020/200915_bhpannualreport2020.pdf (accessed January 2021).

5. Linking Olympic Dam and the Cariewerloo Basin: Was a sedimentary basin involved in formation of the world's largest uranium deposit?;Cherry;Precambrian Research,2017

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