New type of gold-bearing mineralization at the Ozernovskое Au-Te-Se epithermal deposit (Central Kamchatka, Russia)

Sh. S. Kudaeva; Кудаева Ш. С.; V. V. Kozlov; Козлов В. В.; E. D. Skilskaia; Скильская Е. Д.; A. V. Sergeeva; Сергеева А. В.; N. D. Tolstykh; Толстых Н. Д.; I. A. Shkilev; Шкилев И. А.

doi:10.31857/S0016777024050056

New type of gold-bearing mineralization at the Ozernovskое Au-Te-Se epithermal deposit (Central Kamchatka, Russia)

作者: Kudaeva S.S.¹, Kozlov V.V.², Skilskaia E.D.¹, Sergeeva A.V.¹, Tolstykh N.D.³, Shkilev I.A.⁴
隶属关系:
1. Institute of Volcanology and Seismology FEB RAS
2. Institute of Geology of Ore Deposits, Petrography, Mineralogy and Geochemistry RAS
3. V.S. Sobolev Institute of Geology and Mineralogy SB RAS, Novosibirsk
4. JSC Siberian Mining and Metallurgical Alliance
期: 卷 66, 编号 5 (2024)
页面: 505-532
栏目: Articles
URL: https://bakhtiniada.ru/0016-7770/article/view/272609
DOI: https://doi.org/10.31857/S0016777024050056
EDN: https://elibrary.ru/ablhwl
ID: 272609

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The ores of the Ozernovsky Au-Te-Se epithermal volcanogenic deposit are located in linear zones of secondary quartzites in volcanic rocks of Neogene age and are represented by linear stockworks and tubes of quartz hydrothermal breccias interspersed with ore minerals — sulfides, tellurides and selenides. A new type of gold-bearing mineralization has been discovered and studied on the upper horizon of the deposit. The main gold mineral is maletoyvayamite (Au₃Se₄Te₆), which forms small inclusions in selenium native tellurium, together with micro inclusions of other, usually also very rare, minerals — bambollaite (Cu_1-x(Se, S, Te)₂), fahlores of the goldfieldite and ústalečite subgroups. This mineral complex could have been formed in the upper part of a boiling hydrothermal system as a result of mixing of the ascending flow of heterogeneous water-steam fluid with oxygen-enriched surface waters and oxidation of the reduced forms of sulfur, selenium and tellurium contained therein. The primary complex of ore minerals is usually partially replaced by several generations of hypergenic minerals: from native selenium and Au-Ag selenides of the early stage to tellurites and selenites of the late stage of oxidation.

关键词

maletoyvayamite, bambollaite, ústalečite, arsenoústalečite, stibioústalečite, Selen-tellurium, Ozernovskoe volcanogenic gold deposit, Kamchatka

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作者简介

Sh. Kudaeva

Institute of Volcanology and Seismology FEB RAS

编辑信件的主要联系方式.
Email: kudaeva.sharapat@gmail.com
俄罗斯联邦, Petropavlovsk-Kamchatsky, blvd. Piip 9, 683006

V. Kozlov

Institute of Geology of Ore Deposits, Petrography, Mineralogy and Geochemistry RAS

Email: v.kozlov@oxinst.ru
俄罗斯联邦, Moscow, Staromonetny lane 35, 119017

E. Skilskaia

Institute of Volcanology and Seismology FEB RAS

Email: kudaeva.sharapat@gmail.com
俄罗斯联邦, Petropavlovsk-Kamchatsky, blvd. Piip 9, 683006

A. Sergeeva

Institute of Volcanology and Seismology FEB RAS

Email: kudaeva.sharapat@gmail.com
俄罗斯联邦, Petropavlovsk-Kamchatsky, blvd. Piip 9, 683006

N. Tolstykh

V.S. Sobolev Institute of Geology and Mineralogy SB RAS, Novosibirsk

Email: kudaeva.sharapat@gmail.com
俄罗斯联邦, ave. Akademika Koptyuga 3, 630090

I. Shkilev

JSC Siberian Mining and Metallurgical Alliance

Email: kudaeva.sharapat@gmail.com
俄罗斯联邦, Petropavlovsk-Kamchatsky, 106 Mishennaya str., 683016

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2. Fig. 1. Schematic geologic map of the Ozernovskoye field (according to Litvinov et al., 1999): 1 - Quaternary loose alluvial deposits; 2 - Quaternary basaltic lava flows; 3 - andesitic lavas (N2 - Pliocene); 4 - subvolcanic bodies of andesibasalts (N1 - Miocene); 5 - lavas and tuffs of andesites and and andesite-dacites (N1 - Miocene); 6 - andesite-dacite subvolcanic bodies (N1 - Miocene); 7 - andesite dikes (N1 - Miocene); 8 - quartz veins; 9 - zones of kaolinite and dickite secondary quartzites with ore-bearing quartz veins; 10 - post-ore faults; 11 - ore-bearing areas: 1 - BAM, 2 - Intermediate, 3 - Khomut; 4 - Prometey; 5 - Kayurkovsky.

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3. Fig. 2. Textural features of Au-Te-Se ores with selenide tellurium and malethoivayamite. (Te1-xSex), selenide tellurium; Py, pyrite; Qz, quartz; Tlr, tellurite; Kln, kaolinite. Photographs of polished gizzards: a - massive texture of ores composed by close intergrowth of seleniferous tellurium with quartz; b - veins of quartz with seleniferous tellurium cement the fragments of occluded rocks with pyrite phenocrysts, photos of two mutually perpendicular slices of one sample; c - characteristic texture of gold-tellurium ore of the Ozernoe deposit - polystage hydrothermal breccia with angular and semi-rolled fragments in the late generation of quartz with seleniferous tellurium; d - large seleniferous tellurium emission in fusion with quartz - fragment in the breccia cemented by thin-crystalline kaolinite aggregate impregnated with secondary tellurite.

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4. Fig. 3. Quartz-kaolinite secondary quartzite (Qz - quartz, Kln - kaolinite group minerals) with phenocrysts of pyrite (Py), rutile (Rt) and extractions of minerals of Woodhouseite (Wdh) - crandallite (Cdl) series: a - image in reflected electrons (BSE); b - image in artificial colors - superimposition of X-ray maps of elements distribution (Ti, S, P, Si, Al, +BSE).

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5. Fig. 4. Plate crystal of malethoivayamite (Mty) in selenide tellurium with bambollaite inclusions. Selenitic tellurium and maletoivayamite are replaced by tellurite (Tlr) and poite (Pgh) as a result of hypergene oxidation, with simultaneous formation of mustard gold (Au) and selenium telluride (SexTe1-x): a - image in reflected light, without polarization; b - image in reflected electrons (BSE), fragment of the image (a), the crystal of maletoyvayamite is corroded and partially replaced by an aggregate of tellurite and telluride selenium with finely dispersed (“mustard”) nugget gold.

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6. Fig. 5. Shapes of maletoyvayamite outcrops of the Ozernovskoye deposit. Images in reflected electrons: a - inclusions of maletoyvayamite, bambollaite and arsenogoldfieldite in seleniferous tellurium; b - inclusion of maletoyvayamite in accretion with bambollaite; c - crystal of maletoyvayamite in seleniferous tellurium is replaced by tellurite (Tlr) with release of nugget selenium at the contact (Se); d - the same image with overlapping maps of distribution of elements (Au, Te, Se, Si, O).

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7. Fig. 6. Variations of composition (atom ratio) of minerals - (sulfo)-selenotellurides Au, Ag, Cu: a - compositions of Au minerals in coordinates Te - Se(+S) - Au(+Ag): maletoyvayamite from deposits Ozernovskoe (1, authors' data) and Maletoyvayamite (2, data from Tolstykh et al, 2020, 2023), 3 - hypergene fisserite, Ozernovskoe; b - compositions of Au and Cu minerals in S - Se - Te coordinates: 1 - bambollaite and 2 - unnamed mineral Cu1-x((S, Se), Te)2+x, authors' data; 3 - bambollaite from Moctezuma (Harris and Nuffield, 1972); 4 - maletoyvayamite (authors' data); 5 - maletoyvayamite and 6 - tolstichite from Maletoyvayam (Tolstykh et al. , 2020, 2023); c - compositions of bambollaite and mineral Cu1-x((S, Se), Te)2+x in coordinates Te - Se(+S) - Cu(+Ag) [see (b)].

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8. Fig. 7. Diagram of variations in the composition of minerals of Te-Se series, combined with the histogram of Se content distribution (148 microprobe analyses): 1 - nugget tellurium (excluded from the sample for the histogram); 2 - selenide tellurium; 3 - telluride selenium; 4 - nugget selenium with sulfur admixture > 0.5 at.%.

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9. Fig. 8. Large spindle-shaped crystals of tellurium selenide in quartz. Image in reflected electrons.

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10. Fig. 9. Highlights of nugget selenide tellurium - images of the sample in Fig. 2g in reflected light: a - accretion of tellurium selenide with quartz and minerals of goldfieldite subgroup (Gf), without polarization; b - differently oriented grains of tellurium selenide with microinclusions of bambollaite (Bmb), Agf - arsenogoldfieldite, polarization, nicoli are parallel; c - the same area, nicoli are crossed.

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11. Fig. 10. Selenide tellurium and microinclusions in it, images in reflected electrons: a - inclusions of maletoyvayamite and seleniferous tellurium in selenium-bearing zonal goldfieldite (Gf) among quartz; b - inclusions of bambollaite and arsenogoldfieldite (Agf) in seleniferous tellurium among quartz; c - inclusions and oriented accretions of bambollaite (Bmb), at the contact with secondary tellurite - nugget selenium (Se), Kln - kaolinite; d - inclusion of bambollaite in association with bogdanovicite (Boh); e - inclusion of bogdanovicite in association with claustalite (Cth), bogdanovicite contains hard to distinguish submicron oriented outgrowths of claustalite; f - inclusions of bogdanovicite in claustalite grains.

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12. Fig. 11. Representative diffraction patterns of reflected electrons of bambollaite and unnamed mineral Cu1-x((S, Se), Te)2, indexed in a tetragonal cell with space group I41/amd (141) by ICSD[75532] as a structural model: a, b - bambollaite, average angular deviation for the indexed pattern (b) 0. 17°; c-e - two identical DOE patterns for two points within the same grain with different sulfur and selenium ratios: c-g mineral composition Cu0.99((S0.70Se0.59), Te0.72))2. 01, average angular deviation for the indicated pattern (d) 0.31°; e-e - bambollaite of composition Cu0.95((Se0.82S0.40), Te0.83))2.05, average angular deviation for the indicated pattern (E) 0.35°.

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13. Fig. 12. Inclusions of zonal faint ore of variable composition (solid solution of goldfieldite Gf - ustalechite Uč series) in selenide tellurium: a - reflected electron image (BSE), accelerating voltage 10 keV; b - the same grain of faint ore, with enhanced contrast to reveal the inhomogeneity of composition. The circles indicate the analysis points, the numbers near the points correspond to the numbers of analyses in Table 5. The darkest region (348) is represented by arsenogoldfieldite with minimal selenium content in this grain (11.01 wt.%), it grows into zones with increasing selenium content up to ustalechites.

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14. Fig. 13. Shapes of outcrops of hypergene minerals replacing primary ore minerals. Images in reflected (BSE) and secondary (SE) electrons: a, b - poite (Pgh) replaces pyrite crystals in quartz, rims of nugget selenium around some relict pyrite grains in poite and at its contacts with quartz, BSE (a) and image in artificial colors (b) - overlay of X-ray element (Se, Fe, Te, S, O) distribution maps on BSE image; c - emmonsite metacrystals (Ems) replace selenitic tellurium along cleavage cracks and contacts with quartz, BSE; d - metacrystals of tellurite (Tlr) with shoots of poite and telluride selenium of variable composition in seleniferous tellurium, image SE with superposition of color X-ray maps of Fe, O, Te, Se; e - relict crystal of maletoyvayamite is enclosed in tellurite, which replaced selenide tellurium, along contacts of maletoyvayamite with tellurite there is developed discontinuous thin border of fisserite (Fis), image SE+BSE with superposition of color X-ray maps of Ag, Au, Te, Se, O; f - fisserite (Fis) is replaced by emmonsite with emission of finely dispersed nugget gold, image BSE.

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15. Fig. 14. Indicated diffraction patterns of reflected electrons of tellurite and poite: a - DOE pattern of tellurite is indicated in rhombic syngony, space group 61 (Pbca), corresponds to tellurite from the database ICSD26844 with SLO 0.20; b - DOE pattern of poite is indicated in rhombic syngony, space group 33 (Pna21), corresponds to poite from the database COD9011949 with SLO 0.23.

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