Genetic implications of pyrite chemistry from the Palaeoproterozoic Olary Domain and overlying Neoproterozoic Adelaidean sequences, northeastern South Australia

Clark, Chris; Grguric, Ben; Mumm, Andreas Schmidt

doi:10.1016/j.oregeorev.2004.04.003

Cited by 90 publications

(35 citation statements)

References 38 publications

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“…The Co/Ni ratio in pyrite has been used by many authors as an empirical indicator of the depositional environment [15,[70][71][72]. The presence of chemical zoning in the pyrite of the Zhengchong gold deposit may reflect fluctuations in temperature and pH [15,72].…”

Section: Implications For Fluid Evolutionmentioning

confidence: 99%

Trace Element Analysis of Pyrite from the Zhengchong Gold Deposit, Northeast Hunan Province, China: Implications for the Ore-Forming Process

2018

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The Zhengchong gold deposit is located in the central segment of the Jiangnan Orogen in northeastern Hunan Province, South China. The host rocks of this deposit are the Neoproterozoic slates of the Lengjiaxi Group and granodiorite. The structures in the Zhengchong gold deposit are dominated by NE-trending reverse faults, which control the gold-bearing veins. The orebody consists of NE-trending laminated quartz veins and NW-trending quartz veins. The alteration styles include silicification, carbonatization, sulfidation, sericitization and chloritization. The Zhengchong gold mineralization can be divided into four stages: Quartz-pyrite (stage I), quartz-pyrite-arsenopyrite (stage II), quartz-polysulfide (stage III) and quartz-carbonate (stage IV). Three generations of hydrothermal pyrite were identified: Disseminated euhedral to subhedral cubes in altered wall-rock (PyI), euhedral to subhedral cubes inter-grown with arsenopyrite and tetrahedrite in quartz veins and wall-rock (PyII), and euhedral cubes with microinclusions (native gold, galena, sphalerite, chalcopyrite, tetrahedrite, and pyrrhotite) or metasomatic textures in sulfide-rich veins or veinlets (PyIII). PyII and PyIII are arsenian pyrite and represent the main Au-bearing minerals. PyI records the lowest concentrations of Au; PyII and PyIII record similar amounts of Au, Cu, Pb, Zn, and Bi, but PyIII is more enriched in Co, Ni, Te, and Se. The substitution of As, Se and Te for S and that of Co and Ni for Fe occurs by direct-ion exchange. Invisible gold is uniformly distributed within the arsenian pyrite, and visible gold fills microfractures in PyII or occurs as inclusions in PyIII. Co, Ni, Cu exhibit positive correlations with Au and a negative correlation between Au + Cu + Co + Ni and Fe reflect that Fe vacancies may have been a major cause of the precipitation of invisible Au and other metal elements in pyrite structure. There are systematic trace element differences between the three generations of pyrite (PyI, PyII, PyIII). The more Co, Ni and Se, Te substitution that occurred for Fe and S, respectively, the greater the increase in the Co/Ni ratio (<1) and the decrease in the Se/Te ratio (<10) in stage III, indicating that a more reduced, lower-temperature metamorphic hydrothermal fluid was present in stage III.

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Section: Implications For Fluid Evolutionmentioning

confidence: 99%

Trace Element Analysis of Pyrite from the Zhengchong Gold Deposit, Northeast Hunan Province, China: Implications for the Ore-Forming Process

2018

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“…Therefore, pyrite can preserve information about the original formation of the sulfides. Trace element compositions of pyrite have been used as genetic fingerprints (e.g., Loftus-Hills and Solomon, 1967); for example, Co/Ni ratios can be used as an empirical indicator of the formation the environment of pyrite (e.g., Davidson, 1962;Loftus-Hills and Solomon, 1967;Bralia et al, 1979;Ivor Roberts, 1982;Bajwah et al, 1987;Raymond, 1996;Craig et al, 1998;Clark et al, 2004;Koglin et al, 2010;Ulrich et al, 2011;Winderbaum et al, 2012). However, the use of this ratio needs to take into account other provenance factors, as obtained from field observations and other data.…”

Section: Implications Of Pyrite Geochemistrymentioning

confidence: 99%

“…Pyrite that forms in different environments has different Co/Ni ratios, and a significant body of research has been devoted to investigating ranges for this ratio; for example, volcanic pyrite is thought to be characterized by Co/Ni ratios of 5-10 (e.g., Price, 1972;Bralia et al, 1979;Brill, 1989;Bechtel et al, 1998;Yan et al, 2003;Zaccarini and Garuti, 2008), whereas sedimentary pyrite has Co/Ni values of ≤ 1 (e.g., Loftus-Hills and Solomon, 1967;Liu et al, 2000;Orgün et al, 2005;Deol et al, 2012), and hydrothermal pyrite generally has Co/Ni ratios of ≥ 1 (e.g., Loftus-Hills and Solomon, 1967;Liu et al, 2000;Clark et al, 2004;Orgün et al, 2005;Pal et al, 2009). The majority of pyrite from the Yuerya deposit has Co/Ni ratios of N1 and can be split into two ranges of ratios: 0.15-1 (n = 37) and 1.05-4.98 (n = 67), although rare pyrite with values of N5 is also present (5.58 and 9.96; Supplementary Table 1).…”

Section: Implications Of Pyrite Geochemistrymentioning

confidence: 99%

“…For example, the presence of trace elements such as Co, Ni, and Se in pyrite is considered to be a reliable indicator of the metallogenic history of a deposit (e.g., Loftus-Hills and Solomon, 1967;Bralia et al, 1979;Huston et al, 1995;Raymond, 1996;Clark et al, 2004;Koglin et al, 2010;Ulrich et al, 2011). Similarly, trace elements in sphalerite can be used as tracers of ore genesis (Cook et al, 2009b;Ye et al, 2011).…”

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confidence: 99%

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Electron microprobe analyses of ore minerals and H–O, S isotope geochemistry of the Yuerya gold deposit, eastern Hebei, China: Implications for ore genesis and mineralization

Kong

Yin

et al. 2015

Ore Geology Reviews

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“…Pyrite has also been investigated for other trace and minor elements. Among them, the contents of Co and Ni in pyrite, specifically its Co/Ni ratios, have been used as an indicator of the environment of pyrite formation (e.g., Loftus-Hills and Solomon 1967;Bralia et al 1979;Clark et al 2004;Marques et al 2006;Koglin et al 2010;Pal et al 2011). Recently, the Co/Ni ratio in arsenopyrite has been applied to constrain the fluid source for an Au-lode deposit (Cabral and Koglin 2012).…”

Section: Introductionmentioning

confidence: 99%

Gold-bearing ferroselite (FeSe2) from Trogtal, Harz, Germany, and significance of its Co/Ni ratio

Cabral¹,

Koglin²,

Brätz³

2013

J. Geosci.

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Ferroselite from Trogtal, the type locality of the cobalt selenide trogtalite, in the Harz Mountains, Germany, forms a trogtalite-ferroselite assemblage in pockets of massive clausthalite in which specular hematite is dispersed. The pockets occur in hematite-impregnated carbonate veins, emplaced in a reddened greywacke of Lower Carboniferous age. Ferroselite contains ~0.2-5.0 ppm Au; trogtalite has even higher Au contents. Ferroselite has Co/Ni ratios mostly above unity. These characteristics likely reflect oxidizing brines with Co/Ni > 1, such as those involved in the formation of sediment-hosted copper deposits.

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Genetic implications of pyrite chemistry from the Palaeoproterozoic Olary Domain and overlying Neoproterozoic Adelaidean sequences, northeastern South Australia

Cited by 90 publications

References 38 publications

Trace Element Analysis of Pyrite from the Zhengchong Gold Deposit, Northeast Hunan Province, China: Implications for the Ore-Forming Process

Trace Element Analysis of Pyrite from the Zhengchong Gold Deposit, Northeast Hunan Province, China: Implications for the Ore-Forming Process

Electron microprobe analyses of ore minerals and H–O, S isotope geochemistry of the Yuerya gold deposit, eastern Hebei, China: Implications for ore genesis and mineralization

Gold-bearing ferroselite (FeSe2) from Trogtal, Harz, Germany, and significance of its Co/Ni ratio

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