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Article

Podiform Chromitites and PGE Mineralization in the Ulan-Sar’dag Ophiolite (East Sayan, Russia)

by
Olga N. Kiseleva
1,*,
Evgeniya V. Airiyants
1,
Dmitriy K. Belyanin
1,2 and
Sergey M. Zhmodik
1,2
1
Sobolev Institute of Geology and Mineralogy, Siberian Branch Russian Academy of Science, pr. Academika Koptyuga 3, Novosibirsk 630090, Russia
2
Faculty of Geology and Geophysics, Novosibirsk State University, Novosibirsk 630090, Russia
*
Author to whom correspondence should be addressed.
Minerals 2020, 10(2), 141; https://doi.org/10.3390/min10020141
Submission received: 26 December 2019 / Revised: 1 February 2020 / Accepted: 2 February 2020 / Published: 7 February 2020
(This article belongs to the Special Issue Innovative and Applied Research on Platinum-Group and Rare Earth Elements: Dedicated to the Work and Memory of Dr. Demetrios G. Eliopoulos, IGME (Greece))
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Abstract

:
In this paper, we present the first detailed study on the chromitites and platinum-group element mineralization (PGM) of the Ulan-Sar’dag ophiolite (USO), located in the Central Asian Fold Belt (East Sayan). Three groups of chrome spinels, differing in their chemical features and physical–chemical parameters, under equilibrium conditions of the mantle mineral association, have been distinguished. The temperature and log oxygen fugacity values are, for the chrome spinels I, from 820 to 920 °C and from (−0.7) to (−1.5); for chrome spinels II, 891 to 1003 °C and (−1.1) to (−4.4); and for chrome spinels III, 738 to 846 °C and (−1.1) to (−4.4), respectively. Chrome spinels I were formed through the interaction of peridotites with mid-ocean ridge basalt (MORB)-type melts, and chrome spinels II were formed through the interaction of peridotites with boninite melts. Chrome spinels III were probably formed through the interaction of andesitic melts with rocks of an overlying mantle wedge. Chromitites demonstrate the fractionated form of the distribution of the platinum-group elements (PGE), which indicates a high degree of partial melting at 20–24% of the mantle source. Two assemblages of PGM have been distinguished: The primary PGE assemblage of Os-Ir-Ru alloys-I, (Os,Ru)S2, and IrAsS, and the secondary PGM assemblage of Os-Ir-Ru alloys-II, Os0, Ru0, RuS2, OsS2, IrAsS, RhNiAs with Ni, Fe, and Cu sulfides. The formation of the secondary phases of PGE occurred upon exposure to a reduced fluid, with a temperature range of 300–700 °C, log sulfur fugacity of (−20), and pressure of 0.5 kbar. We have proposed a scheme for the sequence of the formation and transformation of the PGMs at various stages of the evolution of the Ulan-Sar’dag ophiolite.

1. Introduction

Podiform chromitites are associated with restite peridotites in ophiolite complexes [1,2,3,4,5]. The concentration, platinum-group element distribution, and mineral form and composition of chrome spinels in podiform chromitites are sensitive indicators of mantle processes: the partial melting degree, initial melt sources, and melt saturation with volatile components (S, H2O, etc.) [6,7,8,9,10,11,12,13,14]. Thus, the geochemical features of chromitites, their distribution and the mineral composition of PGE can be used to evaluate the physical–chemical parameters, mineral equilibria parameters, initial melt composition and geodynamic setting of ophiolite formations [14,15,16,17,18,19,20,21,22]. The use of an olivine–chrome spinel and olivine geothermometer, as well as experimental data on the temperature equilibria of the primary PGMs, provides important information on the formation temperatures of the mantle olivine spinel PGM assemblage and deformation processes [23,24,25]. The chemical composition of chrome spinels and PGMs, the microstructural features of this assemblage, and accessory sulfide mineralization give important information for the reconstruction of magmatic, hydrothermal, and metamorphic processes. In this paper, we describe the chemistry of chrome spinels, the geochemical features of chromitites and PGMs from chromitites, the physical–chemical parameters of mineral equilibria, and the alteration of PGE–chromite mineralization in the mantle peridotites of the Ulan-Sar’dag ophiolite.

2. Materials and Methods

Twenty-one samples of chromitites from the western part of Ulan-Sar’dag were studied. The chemical composition of chrome spinels and olivines and the Al2O3 impurities in olivine were determined by wavelength-dispersive analysis using a Camebax-micro electron microprobe from the Sobolev Institute of Geology and Mineralogy, Russian Academy of Science, Novosibirsk, Russia (Analytical Center for multi-elemental and isotope research SB RAS). A JEOL JXA-8100 analysis methodology specific to olivines to obtain their trace elements has been elaborated: The accelerating voltage is 20 kV, the probe current is 400 nA, and the counting time per line and background measurement are both 10 s. The number of measurements per analysis is 25 [26]. For an error of 10 relative %, the quantitation limit of Al2O3 is within 45–100 ppm. The analytical conditions for olivines and chrome spinels are as follows: The accelerating voltage is 20 kV, the probe current is 30 nA, the beam size is 2 µm, and the signal accumulation time is 10 s. The standards used were natural and synthetic silicates and oxides. The detection limit for oxides was 0.01–0.03 wt. %.
The content of PGE in chromitites and dunites was determined in the rocks using the ICP-MS microprobe and kinetic methods, along with pre-concentration (nickel matte), at the TsNIGRI analytical laboratory (Moscow, Russia). The ICP-MS microprobe method with pre-concentration (nickel matte) involves melting the probe (50 g) at 1100 °C, during which two phases are formed: A sulfide (nickel matte) and an oxide (skimming) phase. These phases are segregated according to the concentration of all noble elements in nickel matte. The collector is an alloy of sulfides and a metal alloy, in which the bulk of the noble metals is collected [27]. The received matte is cleaned through skimming and crushed for 10–15 s. A portion of the matte is dissolved in hydrochloric acid, while the Ni and Cu of the matte are almost completely dissolved. Platinum metals in the nonsolute residue are dissolved in a mixture of hydrochloric and nitric acids. The mass concentration of Pt, Pd, Rh, Ru, and Ir in the solution is determined by ICP-MS. Osmium is separated from other noble metals by distillation. The method is based on the ability of osmium to form volatile tetraoxides under oxidizing conditions [28]. The determination of the osmium concentration was carried out using a kinetic method. The method is based on the catalytic effect of osmium in indicator oxidation-reduction reactions. The reaction rate depends on the concentration of the catalyst [28,29,30]. The detection limits were 2 ppb for Os, Ir, Ru, and Rh; and 5 ppb for Pt and Pd.
The studied platinum-group minerals were polished plates (21 pieces) and heavy fractions, extracted from chromite ores. The selected PGM grains were mounted in epoxy blocks and polished with a diamond paste for further analysis. Microtextural observations of PGM were performed by means of reflected-light microscopy. The chemical composition of PGMs was determined using a MIRA 3 LMU scanning electron microscope, with an attached INCA Energy 450 XMax 80 microanalysis energy dispersive system, at the Sobolev Institute of Geology and Mineralogy, Russian Academy of Science, Novosibirsk, Russia (Analytical Center, IGM SB RAS). Pure metals were used as the standards to determine the chemical composition of the PGE, Ni, and Cu; arsenopyrite was used for As; and pyrite was used for Fe. The minimum detection limits of the elements (wt. %) were found to be 0.1–0.2 for S, Fe, Co, Ni, and Cu; 0.2–0.4 for As, Ru, Rh, Pd, Sb, and Te; and 0.4–0.7 for Os, Ir, and Pt.

3. Geological Setting

The ophiolite complexes are widely distributed in the south-eastern part of Eastern Sayan (Siberia, Russia) (Figure 1).
The ophiolites are localized in the form of extended branches in the south (Il’chir) and north (Holbin-Hairhan). The features of these ophiolites are as follows: rock associations, geochemical and mineralogical characteristics, a geological structure resembling individual “massifs”, geodynamic conditions and a formation time, which are actively studied for a considerable time. Dobretsov and Zhmodik et al. obtained data on the heterogeneity of ophiolites of the south-eastern part of Eastern Sayan (SEPES) [32,33]. They indicate that the ophiolites of the southern branch were formed in a mid-ocean ridges setting, and ophiolites of the northern branch were formed in an island arc setting [32,33,34,35,36,37,38]. The Ulan-Sar’dag ophiolite (USO) occupies a special structural position in the Eastern Sayan and Central Asian Fold Belt (Dunzhugur island arc). The USO is a tectonic plate, which is located between ophiolites of the southern and northern branches of the Dunzhugur island arc, near the contact zone of the Gargan “block” gneisses, with granites of the Sumsunur complex. The USO is underlaid by volcanogenic and sedimentary rocks of the Ilchir suite and limestones of the Irkut suite. Ophiolites include mantle restites (dunites, harzburgites), podiform chromitites, cumulates (metawehrlite, metapyroxenite, metagabbro), a basic dike and a volcanic complex (Ilchir suite) (Figure 2 and Figure 3). USO has a lenticular body that is elongated in the east–west direction and is 1.5 × 5 km2. It is composed of dunites and harzburgites. Harzburgites predominate in the central part, dunites and serpentinites prevail in the margin, and the latter lie in contact with the volcanogenic-sedimentary sequence of the Ilchir suite. The rocks of the cumulative series are metamorphosed under the conditions of epidote-amphibolite and amphibolite facies. The volcanogenic-sedimentary sequence is composed of volcanic, volcanogenic-sedimentary, and metasedimentary rocks (black schists and marbles). Volcanogenic-sedimentary rocks are sulfurized, and sulfide mineralization is confined to the schistosity zones. High-Ti basalts (MORB tholeiites), boninites, and island-arc andesites are distinguished in the volcanic complex. All rocks in the ophiolite nappe bottom are intensively deformed and mark the thrust zone. They include numerous crushing zones, signs of shear displacement and gliding planes. In the contact zone of serpentinites and rocks of the Ilchir suite, the talcum powder zones and zones of actinolite-tremolite composition are widely manifested.
The types of schlieren, lenticular, and vein-like chromite bodies are localized in dunites and serpentinites (Figure 4). The length of schlieren and massive chromitite bodies ranges from a few centimeters to several meters, and their width varies from 5 cm to 0.5 m. The predominant structural-textural type is a massive chromitite. In some schlieren chromitites, the tectonic flow structures (Figure 4e) and the “snowball” type (Figure 4f) are observed.

4. Results

4.1. Podiform Chromitites

Massive chromitites are the predominant petrographic variety of rocks in the mantle peridotites of the USO; disseminated, schlieren, and rhythmically-banded ores are less common. Chrome spinels make up 80–95 vol. % of massive chromitites. The intergranular space is filled with olivine and secondary silicates: serpentine, chlorite, and, rarely, talc. The structure of massive chromitites varies from fine-grained to coarse-grained. The crystal bodies vary from subidiomorphic grains (0.1–0.5 cm) to allotrimorphic aggregates of grains of up to 1.5 cm in size. Chrome spinels have a cataclastic texture, and they are partially fragmented. The grains are dissected by cracks filled with secondary silicates. In the central part, chrome spinels are unchanged, and in cracks and on the grain rims, they are often replaced by chrome magnetite. Some grains contain olivine inclusions. A wide range of minerals show accessory mineralization in chromite ores: PGMs, sulfides, sulfarsenides, and sulfosalts of base metals (Figure 5).

4.1.1. Chrome Spinels

According to the chemical composition, ore chrome spinels are divided into three groups and are represented by chrome picotite, alumo-chromite, chromite, chrome-magnetite and magnetite (Table 1, Figure 6). In one sample, chrome spinels of all three groups may be present. Chrome spinels of groups I, II, and III have the following compositions (wt. %): Al2O3 = (17–43), (7–16), and (9–18); Cr2O3 = (26–54), (46–66), and (47–57); MgO = (10–20), (9–13), and (8–10); and FeO = (6–14), (1–18), and (18–20), respectively. In chromitites of the USO, chrome picotites are found, which is typical only of this massif, in contrast to chrome spinels from other ophiolite complexes of the southeastern part of East Sayan [38]. Chrome spinels have a homogeneous composition. Altered chrome spinels demonstrate increased contents of FeO, MnO, NiO, ZnO, and Fe2O3 and decreased contents of Cr2O3 and Al2O3. Chrome spinels are often replaced by chrome magnetite and magnetite along the cracks.

4.1.2. Olivine

Olivine in chromitites occupies the intergranular space of chrome spinels; it is often replaced by serpentine or chlorite. The data, which correspond to chrysotile and forsterite, are shown in Table 2. The MgO content is 49–54 wt. %, and the NiO variations are insignificant and amount to 0.37–0.42 wt. %, which corresponds to olivines from depleted peridotites. The fraction of the Fo component is 92–97.

4.2. Geochemistry of Platinum-Group Elements

The content of PGE in mantle peridotites and podiform chromitites was determined. The content of PGE in dunites and serpentinites is 94–180 ppb; in chromitites, it ranges from 242 to 992 ppb (Table 3). The PGE content increases with an increase in the volume percentage of chromite in the rock. In addition, depending on the proportion of the chromite and silicate components in the rock, the IPGE/PPGE ratio changes (Figure 7a,b) (IPGE: Os, Ir, and Ru; PPGE: Rh, Pt, and Pd). For example, in massive ores (85–95 vol. % of chromite), IPGE > PPGE, and IPGE/PPGE = 0.86–2.15. In schlieren lenticular chromitites and chromitites with deformational textures, the PPGE proportion increases and amounts to IPGE/PPGE = 0.03–0.67. In chromitites I, the IPGE/PPGE is higher than in chromitites II (Table 3).

4.3. Mineralogy of Platinum-Group Elements

The first data on PGE mineralization (PGM) in chromitites of USO have been obtained. The chemical composition of the minerals is presented in Table 4, and classification diagrams are presented in Figure 8a,b. Primary and secondary PGMs have been distinguished. The most common platinum-group minerals in the chromitites of the USO are PGE sulfides: laurite-erlichmanite (Ru,Os)S2, with different Ru/(Ru + Os) ratios. Other PGE phases are represented by high-temperature Os-Ir-Ru alloys-I, phases of variable-composition Os-Ir-Ru alloys-II, native Os, Ru, sulfarsenides of (Os, Ir, Ru), and zaccarinite RhNiAs. The primary and secondary PGMs will be described separately.

4.3.1. Primary Platinum-Group Minerals

High-temperature Os-Ir-Ru alloys-I are in the form of idiomorphic inclusions in chrome spinels, and xenomorphic grains are intergrown with laurite. Single grains contain inclusions of (Ru,Os)S2 of less than 10 µm in size. The alloys are enriched with Os, and its content varies from 71 to 79 wt. %; the content of Ir ranges from 20 to 28 wt. %; and the content of Ru is very low and ranges from 2 to 5 wt. %. There are some impurities of Fe and Ni. In the classification diagram, the compositions of the primary alloys correspond to osmium with low contents of Ir and Ru (Figure 8a). Dissolution microstructures are observed in some grains (Figure 9).
Laurite-Erlichmanite (Ru,Os)S2
Sulfides can be divided into two groups, according to their composition and microstructural features (Table 4). The first group, laurite I, contains laurite-erlichmanite with a homogeneous composition.
Laurite-erlichmanite occurs as an inclusion in chrome spinels (10–15 μm), and in some cases, it can be intergrown with amphibole (magnesio-hastingsite hornblende) in chrome spinel or be found as individual grains (Figure 9c,d). The ratio, Ru’ = Ru/(Ru + Os), is 0.61–0.78. The content of Os is 20–33 wt. %, and Ru is 27–40 wt. %. In the classification diagram, they are in the laurite field (Figure 8b). The second group, laurite II, contains laurites of a heterogeneous composition, containing micro inclusions of (Os-Ir-Ru) II alloys and laurites, which are replaced by PGE sulfarsenides (Figure 9e–g). Laurite II (Lr II) is characterized by wide variations in the contents of Os of 1.2–49.9 wt. %, Ru of 20.8-62.2 wt. %, and the Ru/(Ru + Os) ratio of 0.44–0.99. In the classification diagram, they are in the fields of erlichmanite and laurite. In the chemical composition of laurite, a sulfur deficiency is often registered (Table 4). Insignificant amounts of irarsite IrAsS are found in the chromitites of the USO, where it replaces laurite. Irarsite forms corrosive, looped structures to replace laurite (Figure 9g,h).

4.3.2. Secondary Platinum-Group Minerals

The secondary PGMs are presented by (Os,Ru)S2—laurite III, native Os and Ru, Os-Ir-Ru alloys-II of a variable composition, irarsite IrAsS, zaccarinite RhNiAs, and (Ru,Ni,Os,Ir,Rh)(As,S) sulfarsenides of a non-stoichiometric composition. The secondary phases are localized in the chloritized silicate intergranular space of chrome spinels. Some grains (micro particles of osmium and other phases) are very small (less than 2–3 µm), and their chemical composition can be determined only semi-quantitatively. In some cases, micro particles of a variable composition (Ru,Ir,Os,Cu,Te,Ni,Ba,S,O) can be found with secondary PGMs. Further, due to their very small size and partial coincidence with the elemental composition of the host mineral, qualitative analysis can also be hampered.
Os-Ir-Ru Alloys-II
Micro particles of Os-Ir-Ru alloys-II are the common phases and are found in a secondary mineral assemblage. They are localized mainly in laurite II, or they are a part of polyphase aggregates with Ni, Cu sulfides, sulfarsenides of Os, Ir, and Ru, zaccarinite RhNiAs, and laurite III (Figure 10a–d). Their composition varies (Table 4, Figure 8a) from native osmium to native ruthenium. Native osmium is composed of (wt. %): Os (87–92), Ir (0–12), and Ru (3–8). Native Ru is composed of (wt. %): Ru (93), Os (2.5), and Ir (2.1). The composition of the (Os-Ir-Ru) II alloys varies, with a wide range (wt. %): Os (30–74), Ir (6–32), and Ru (8–58).
Laurite III
The occurrence forms of secondary laurite III are very diverse. It is mainly localized in Cr-containing chlorite, where it forms polyphase aggregates with PGE-containing chalcocite (Cu2S) (Figure 10a), recrystallized PGM aggregates with native Os (Figure 10b), micro particles in association with Ni3S2, NiS and phases of a non-stoichiometric composition (Ru,Ir,Os,Cu,Te,Ni,Ba,S,O) (Figure 10c). The following features are characteristic of laurite III: a) A porous structure, with Cr-bearing minerals of the chlorite group in the voids, and b) a very small grain size (micro particles). The chemical composition corresponds to the end member of the laurite-erlichmanite solid solution: RuS2-OsS2 (Figure 8b). Laurite III is characterized by very low Os and Ir contents and the absence of Rh. Sometimes it contains Ni impurities. The value of Ru′ varies insignificantly and amounts to 0.93–1 (Table 4); in turn, OsS2 has low contents of Ru and Ir and is located in a recrystallized aggregate with laurite III and native Os (Figure 10b).
The (Ir,Os,Ru)AsS in the secondary association is in the form of polyphase aggregates. It replaces laurite. It contains Os and Ru in insignificant amounts. Secondary irarsite is presented as very small microparticles (less than 5 µm) in chlorite in association with Ni3S2 and laurite III.
(Ru,Ni,Os,Ir,Rh)(As,S) is found in the form of micro particles (7 μm) in a polyphase aggregate, consisting of laurite II and NiS (Figure 9f). There is a deficit of S and As in this phase.
Zaccarinite RhNiAs is found in polyphase aggregates in association with Ni3S2, secondary (Os-Ir-Ru) II alloys and native Ru (Figure 10d).
Unknown phase No. 1 (Ir,Ni,Cu,Ru,Os,Cl) is found in the intergrowth with laurite, erlichmanite, and chalcocite. This association is localized in chromite in the cracks filled with Cr-containing chlorite. It is worth noting the presence of Cl in this phase.
Unknown phase No. 2 (Os,Ir,Ru,As,S,O) is found in the millerite cracks in close association with chlorite and chrome-magnetite.
Unknown phase No. 3 (Ru,Ir,Te,Ni,Ba,S,O) is found in chlorite in the intergrowth with laurite and irarsite. The Ba and Te impurities are unusual for the platinum phases of chromitites.
Ni,Fe,Cu sulphides and arsenides. The sulphides of base metals form a dispersed impregnation mainly in serpentine-chlorite aggregate. Heazlewoodite Ni3S2 and millerite NiS are the predominant sulfide phases (Figure 5, Table 5). Heazlewoodite is often found in polyphase aggregates with secondary PGE minerals. It has a homogeneous composition and is identical in individual grains and in the intergrowth with platinum metal phases.

5. Discussion

5.1. Chromitite Formation: Composition of Parental Melts

Chromite bodies in ophiolites are formed due to the partial melting of rocks of the upper mantle. The interaction of the melt with mantle peridotites plays an important role in the formation of podiform chromitites. In the channel filled with molten mantle, the ascending olivine-chromite-cotectic melt mixes with the silica-enriched melt, formed through the harzburgite-melt reaction. The formation of surrounding dunites along the host harzburgites is the result of a combination of olivine precipitation from “older” magma and the destruction of orthopyroxene in harzburgite, interacting with the magma channel. Thin chromite schlieren and streaks can be formed by separating the chromite from the cotectic olivine-chromite melt [9,42,43,44,45,46].
In the Pt/Pt*-Pd/Ir diagram (Figure 11), dunites and chromitites are within the partial melting trend. The late metamorphic and hydrothermal processes, during which Pd enrichment occurred, probably cause the high Pd/Ir ratio in some Ulan-Sar’dag chromitites. In the OSMA diagram, most of the ore chrome spinels are in the olivine-spinel equilibrium field, and some of the chrome spinels are beyond this field. This can be explained by the distortion of the magmatic system closedness, changes in the compositions during the tectonic processes and metamorphism of chrome spinels. Chromitites of the USO were formed at the 28–35% degree of partial melting (Figure 12). The data on the dunites, harzburgites, and chromitites of the northern and southern branches of the Ospa-Kitoy ophiolite are presented for comparison (Figure 12). The Mg′(Ol)–Cr′(Sp) ratio in dunites and harzburgites corresponds to the 30–40% degree of partial melting; in ore chrome spinels from the northern branch, it corresponds to 30–40%; in ore chrome spinels of the southern branch, it corresponds to 35%.
The composition of the chrome spinels of the USO varies significantly, which may reflect the interaction of mantle peridotites with the melts of various compositions. The joint presence of high-Cr′ and high-Al′ chrome spinels is common in many ophiolite belts, but as a rule, chrome spinels with different compositions are found in different ophiolite nappes [7,9,52,53,54,55,56,57,58,59]. Their joint occurrence in one ophiolite nappe is less common; in this case, the ophiolite nappe, as a rule, contains peridotites depleted to different degrees [45,60,61,62,63]. The composition of chrome spinels of podiform chromitites that includes, as the main components, FeO, MgO, Al2O3, and TiO2 is a function of the composition of the parental melts [9,15,16,18,21,64]. We have calculated the contents of the Al2O3, TiO2 and FeO–MgO ratios in the parental melts, which were in equilibrium with the podiform chromitites (Table 6), according to Equations (1)–(3) [15]. Table 6 shows, for comparison, the values of these parameters for the chrome spinels of ophiolites from around the world.
Al2O3Sp(wt. %) = 0.035 × (Al2O3)melt2.42,
TiO2(melt)(wt. %) = TiO2Sp0.82524 × e0.20203
Ln(FeO/MgO)Sp = 0.47 − 1.07 × Al′Sp + 0.64 × Fe3+′ + Ln(FeO/MgO)melt, where Al′Sp = Al/(Al
+ Cr + Fe3+) and Fe3+Sp = Fe3+/(Al + Cr + Fe3+)
The chemical composition of the chrome spinels I group (Crsp I) and the composition of the parental melt are similar in these parameters for medium-aluminous chrome spinels of the Ospa-Kitoy ophiolite (Table 6). The (Al2O3)melt value of Crsp I is 13–18 wt. %, and the Al2O3Sp / Al2O3melt ratio corresponds to the spreading trend and abyssal peridotites (Figure 13a). Despite the low TiO2 content, Crsp I has the TiO2Sp/TiO2melt trend, which is calculated for spinels from the MORB-type peridotites (Figure 13b).
The chemical composition of the chrome spinels II group (Crsp II) and the composition of the parental melt are similar in these parameters for the low-Al′ chrome spinels of the Ospa-Kitoy ophiolite (Table 6). The (Al2O3)melt values for the chrome spinels of groups II and III are 10–12 and 10–13 (wt. %), and the (FeO/MgO)melt ratio is 0.4–0.85 and 0.7–1, respectively. The values of the Al2O3Sp/Al2O3melt ratios in chrome spinels II and III correspond to the trend of the chrome spinels from the island-arc boninites and chromitites of the Ural-Alaska complexes (Figure 13c). The (TiO2)melt values for the chrome spinels I, II, and III groups overlap because of the low TiO2 content (0–0.2 wt. %). In general, the values of (Al2O3)melt/(FeO/MgO) are similar to the high-Cr′ chrome spinels from the Troodos and Zetford Mine ophiolites (Figure 13d), which were formed in a suprasubduction setting. In the discrimination relationship diagrams, the [Al2O3/Fe2+/Fe3+], [Mg′/Cr′], and [Al2O3/TiO2] (Figure 14a–c) of the chrome spinels I group are in the field of the MORB–type peridotites. Chromitites were formed during the interaction of harzburgites with primitive MORB-like melts at deep levels of the upper mantle. Through the interaction of MORB-type melts, which are in equilibrium with abyssal dunites [65,66], precipitation of chrome spinels with Cr′ 0.4–0.6, as a product of the melt–peridotite reaction, is possible [43,67]. Among the volcanic rocks of the USO, metabasalts, with enriched mid-ocean ridge basalt (E-MORB) geochemical characteristics, are available [68].
The chrome spinels II group is localized in the boninite field. The TiO2 and Al2O3 content corresponds to the chrome spinels of the suprasubduction peridotites and overlaps with the chrome spinels from the New Caledonia island arc (Figure 14c). The chrome spinels II are formed during the reaction of the peridotites with the island-arc boninite melt in the subduction zone. The chrome spinels III group lies on the boundary of the boninite fields and magmatic complexes of the Ural-Alaskan type. Three mechanisms can be suggested for the formation of the third type of chrome spinels. The first is the interaction with high-iron low-titanium melts [81]. The second mechanism is through plastic deformations under mantle or crust-mantle conditions (low fO2, Table 1), because of the reactions of the Mg-Fe exchange with olivine. High-iron chrome spinels are found in the structural types of chromite, including chromitites with deformation structures. When compared with chrome spinels of the Alaskan type chromitites, the chrome spinels III group from the chromitites of the USO have low TiO2 contents, high Cr2O3 contents and low (mantle) fO2 values (Table 1). Variations in TiO2 contents, from 0 to 0.22 wt. %, may indicate a reaction with TiO2-containing melts [82]. The third mechanism is through the partial melting of the fluid-metasomatized mantle during the interaction of andesitic melts with rocks of an overlying mantle wedge [71,83,84].

5.2. Spinel and Olivine Geothermometers and Olivine-Spinel Oxybarometers

Several processes condition the composition of chrome spinels: partial melting, cooling of mantle peridotites and plastic deformations in the upper mantle. Many researchers have shown that, during ultramafite cooling, regardless of their formation (mantle or cumulative), (Mg ↔ Fe2+) exchange reactions take place between coexisting olivines and chrome spinels, as a result of which the coefficient of these elements’ distribution increases in favor of chrome spinels, and consequently, the calculated temperatures of the olivine-spinel equilibrium decrease [85,86,87]. During plastic deformations, exchange processes and rebalancing between olivine and chrome spinels also occur, and schlieren and lenticular segregations of chromitites transform into massive chromite bodies (Figure 4c–f). Based on this, it is assumed that the obtained values for the temperature, pressure and oxygen fugacity correspond not to the formation of ultramafites and chromitites, but to the stages of the formation and transformation of these bodies: the tectonic flow of the upper mantle rocks, the effect of metasomatizing fluids and other processes.
We have calculated and estimated the P-T parameters with the help of an olivine-spinel (Ol-Sp) geothermometer, provided in [88]. The oxygen fugacity was determined using an Ol-Sp oxybarometer, provided in [89], in accordance with oxybarometers [90,91]. For the chrome spinels I group (high Al′), the calculated temperatures of the Ol-Sp equilibrium are TOl-Sp = 1020–920 °C, and fO2 = (−0.7)–(−1.5) (Table 1); for the chrome spinels II group (medium-, low-Al′), the calculated temperatures are TOl-Sp = 891–1003 °C, and fO2 = (−1.1) − (−4.4); for the chrome spinels III group, these values are TOl-Sp = 846-738 °C, and fO2 =(−1.49) − (−3.01). For the chrome spinels containing inclusions of laurite-erlichmanite, TOl-Sp = 916–938 °C, and fO2 = −2.4. For the chrome spinels with the olivine inclusion, TOl-Sp = 991.6 °C, and fO2 = (−1.3). The temperature values overlap, but for the chrome spinels II group, higher temperatures are noted. The values of fO2 are discrete. It is assumed that a more reducing environment and higher solid-phase reaction temperatures are required for the formation of the chrome spinels II group, in comparison with the chrome spinels groups III and I. The content of impurities (Al2O3) in olivine was used as an alternative geothermometer. For our objects, this method was limited by the small amount of preserved olivine. We were interested in the chromitites containing PGE- and PGE-free mineralization. Using the geothermometer of De Hoog and Gall for the Al content in olivine [25], the temperature was estimated by Equation (4). For the chromitites containing PGM, the temperature, according to the olivine thermometer, was 893–1332 °C, and for the PGM-free chromitites, it was 1073–1225 °C (Table 1).
Tol(C) = 1087/(7.46 − lnAlppm) − 273
An assessment of the temperature using an olivine thermometer and inclusions of primary high-temperature (Os-Ir-Ru)-I alloys gives the values of 1200–1300 °C, which is more consistent with the expected temperatures of the chrome spinel formation from the melt.

5.3. Distribution of PGE in Mantle Peridotites and Chromitites

The form of PGE distribution in the mantle peridotites and chromitites of ophiolites reflects the mantle conditions of chromitite formation and PGE mineralization. In the process of partially melting the mantle source, the PGEs fractionate. The melt is enriched in Rh, Pt, and Pd (PPGE), since PPGE is incompatible with Os, Ir, and Ru (IPGE). The mantle restite will be enriched in IPGE [17,92,93]. This process is confirmed by the form of PGE distribution in the Ulan-Sar’dag peridotites (Figure 15a,b), for which ∑IPGE> ∑PPGE.
In the case of a low degree of partial melting, there are no obvious differences between the PPGE and IPGE contents, and the PGE distribution is flat. At a high degree of partial melting, PPGE is depleted in restite mantle rocks, relative to IPGE, and the total PGE contents become lower. In this case, the distributions have a negative slope. The PGE distribution in the mantle peridotite of Ulan-Sar’dag demonstrates: (1) a positive Ru and Pd picks; (2) a flat type of distribution, with a negative slope towards Pd; (3) a positive slope of Ir, Rh, and Pt and a negative slope of Ru (Figure 15b). Podiform chromitites are characterized by a fractionated form of PGE distribution (Figure 15c), which indicates a high degree of partial melting (about 20%–24%) of the mantle source. Three types of PGE distribution are observed in Ulan-Sar’dag chromitites (Figure 15d): (1) a negative slope from Os to Ir and Ru to Pt and a positive slope from Ir to Ru and Pt to Pd; (2) a negative slope of the distribution curve from Os to Pt and a positive slope from Pt to Pd; (3) low contents of Os, Ir and Ru and an enrichment in Rh (Pd is uncharacteristic of chromitites). Chondrite-normalized PGE relations in chromitites of the USO are similar to those of chromitites of ophiolites (Figure 15c,d) formed in a suprasubduction environment from all over the world [7,11,57,63,96,97,98]. The pronounced positive Ru anomaly is due to the predominant laurite phase in the chromitites of the USO. It is known that Ru has a maximum affinity with S, and the predominance of IPGE sulfides, in turn, indicates a high fugacity of sulfur in the melt, in contrast to the parental melts for chromitites of the northern and southern branches of the Ospa-Kitoy ophiolite (Figure 16a–c).
The experimental data show that Os, Ir, and Ru are concentrated by trapping submicroscopic clusters of these elements in the metallic state during chromite crystallization [99,100,101]. Tsoupas [49] believes that an IPGE enrichment in chromitites can be associated with post-magmatic processes during a long period of deformations, beginning from plastic deformations in the asthenospheric mantle and ending with brittle deformations in the crust. This is confirmed by wide variations in the contents of IPGE, PPGE and the IPGE/PPGE ratio from 0.03 to 2.15 (Table 3) in the studied chromitites. Negative Pt anomalies in chromitites are closely related to the unique properties of Pt itself. The distribution coefficients of the alloy/sulfide liquid at 1000 °C are 1–2 for Pd and more than 1000 for Pt. Thus, the distribution coefficient of the alloy/sulfide melt for Pt is 1000 times greater than it is for Pd [102]. This is confirmed by the distribution diagrams, where a Pt negative anomaly is clearly visible (Figure 15c,d). An extreme Pd enrichment in one of the chromitites is most likely associated with late magmatic processes and exposure to the reduced fluid. Chrome spinels has high FeO contents and low fO2 values. There are no Pd phases in this chromite. We believe that PGM is concentrated in recrystallized dunite, which requires further study. Detailed studies on the metaperidotites, metagabbros, and metavolcanogenic sedimentary rocks of the USO showed that some rocks have signs of significant exposure to a high-temperature fluid phase, which leads to rock metasomatism [68,103].

5.4. Sequence of the Formation and Transformation of the Platinum-Group Mineral Assemblage

Based on the chemical and textural features of PGM and associations with the magmatic and hydrothermal minerals of chromitites, several stages of PGE mineralization were distinguished (Figure 17).
• I—Magmatic Stage
At the magmatic stage, under the upper mantle conditions, euhedral–subhedral high-temperature Os-Ir-Ru I alloys and laurite I are formed (Figure 8 and Figure 9a–d), which are captured by chromite grains [5,11,22,104,105,106]. The high osmium content in the primary (Os-Ir-Ru) I alloys is caused by an early crystallization of laurite-erlichmanite (Figure 9c). According to the experimental data, laurite without an Os impurity crystallizes from the melt at a high temperature (T = 1200–1300 °C), P = 5–10 kbar and low log sulfur fugacity (fS2), from (−0.39) to 0.07 [24,106,107,108,109]. A decrease in temperature and increase in fS2 leads to a replacement of Ru by Os, and as a result, laurite rich in Os is formed. The predominance of laurite-erlichmanite over solid (Os-Ir-Ru) solutions in the chromitites of the USO is a distinctive feature, in comparison with the PGE mineralization of the northern and southern branches of the Ospa-Kitoy ophiolite (Figure 16a–c). In combination with the high and medium Al′ chrome spinels, this indicates the formation of chromitites and PGE mineralization of the USO because of the interaction between the initially S-saturated tholeiite magma and depleted harzburgites. Sulfarsenides and arsenides of Ru and Ir are formed from the residual fluid phase at the late magmatic stage (Figure 10g,h). With magmatic system cooling, volatile components, such as S and As, accumulate with the formation of the residual fluid phase. There is a partial replacement of laurite by irarsite with the formation of laurite II.
• II—Stage of Serpentinization and Exposure of Fluid
The PGMs in chromitites demonstrate signs of PGE remobilization (Figure 10a–d). The most intense changes of PGMs occur at the stage of the serpentinization of ultramafites. A fluid–rock interaction occurs with the participation of reduced gases (H2, CH4) and the H2O of mantle origin. Dehydrating rocks of the subducting slab, as well as mantle-reduced fluids penetrating along the fault zones in tectonically weakened sectors, serve as the fluid source. At this stage, the following platinum–metal phases are formed: native Os and Ru, (Ir-Ru) alloys, phases of a variable (Os-Ir-Ru) composition, and newly formed laurite III, IrAsS, RhNiAs and RuAs (Figure 9f and Figure 10a–d). Remobilized secondary PGMs form polyphase aggregates in the serpentine-chlorite matrix (Figure 10c) in association with Ni sulfides, sulfarsenides, and arsenides. The joint occurrence of PGMs with Ni sulfides and the presence of such elements as Ni, Fe, Te, Cu, Co, As, and Sb in the platinum phases indicate PGE mobility in a fluid-saturated medium. The processes of the redistribution and concentration of PGE, including refractory Os, Ir, and Ru, occur at relatively low temperatures, reducing conditions corresponding to the formation of nickel sulfides, sulfarsenides, and arsenides, and low-temperature PGE-bearing intermetallides [110]. At the initial stage, the penetration of fluid through the permeable zones into laurite-erlichmanite led to the desulfurization of sulfides, a deviation from stoichiometry, the appearance of microdefects in the crystal lattice, and the formation of nanopores on the grain surface. These processes led to the formation of microporous structures and the separation of native Os and Ru (Figure 9e,f) [108,109,111,112]. According to the experimental data, congruent RuS2 → native Ru decomposition occurs at T = 300 °C, log fS2 = (−20), and P = 0.5 kbar [113,114,115,116,117,118]. The (Os-Ir-Ru) phases of a variable composition are probably the products of changes in (Os,Ir,Ru)AsS, since Ir has a maximum affinity with As, and irarsite therefore survives for the longest. At the same stage, secondary (newly formed) laurite III can be formed. They grow over primary laurite-erlichmanite or are confined to chloritization zones, and as a rule, they are in association with nickel and copper sulfides and sulfarsenides (Figure 10a). Irarsites IrAsS can be formed during serpentinization. In this case, irarsites are in close association with Ni3S2, forming joint aggregates. The microstructural features of such aggregates indicate their simultaneous formation (Figure 10c). The physical–chemical modeling of the forms of PGE transport in the fluid systems indicates the formation of carbonyl, chloride, hydrosulfide, and bisulfide complexes, in the form of which they are transported, and the formation of secondary PGM occurs. When PGEs are transported by bisulfide complexes, and As and Sb appear in the system, PGE solubility decreases, the composition of the solution changes, and the system deviates from equilibrium. Sulfur released from bisulfide complexes reacts with Ni to form Ni3S2.
• III—Stage of Ophiolite Obduction. Regional Metamorphism.
As the ophiolite rises to the surface, the rocks undergo repeated processes of serpentinization under the influence of metamorphogenic fluids with an increased activity of O2, As, and Sb [48]. In chromitites, chrome spinels change into chrome magnetites or magnetites. There are no clear criteria for distinguishing remobilized PGMs under the crustal conditions (under the influence of metamorphogenic fluids). We believe that non-stoichiometric platinum-metal phases, containing Cu, Te, As, Sb, and O, could be formed under the crustal conditions. These elements can be transported by aqueous solutions, with a subsequent re-deposition [119,120]. These events are mainly controlled by the Eh-pH conditions, and these minerals can be formed directly in the supergenic environment. Under the conditions of a changing temperature, varying Eh-pH in the Os-S-O-H system, low f(S2) and exposure to an oxidizing high-temperature fluid at a temperature of about 500 °C [121], Os becomes more mobile than other PGEs, which leads to the further redistribution and redeposition of osmium. At this stage, the following PGE-containing phases can be formed: (Ru,Ir,Te,Ni,Ba,S,O), (Os,Ir,Ru,As,S,O), and (Ir,Ni,Cu,Ru,Os,Cl). Most often, such phases are localized in the micro voids of early PGMs (laurite, irarsite, etc.). Another process of PGM changing is the enlargement and agglomeration of PGE nanoparticles to the micro level. During progressive metamorphism (epidote-amphibolite and amphibolite facies) and/or a thermal event (introduction of granite intrusion), the changed P-T conditions affect the stability of nanoparticles. As the temperature rises to 590–650 °C, the nanoparticles in the sulfide matrix become unstable [122], which leads to their coalescence (Figure 10b) and enlargement (to micron sizes). The accessory mineralization of the crust-metamorphogenic stage is represented by the products of the changes in Ni, Fe, and Cu sulfides and sulfarsenides, with the appearance of oxygen-containing phases of a non-stoichiometric composition.

6. Conclusions

(1) High- and medium-Al′ chrome spinels were formed through the interaction of mantle peridotites with tholeiite melts in a spreading setting. High-Cr chrome spinels were formed during the interaction of mantle peridotites with boninite melts in suprasubduction environments. The predominance of PGE sulfides over high-temperature Os-Ir-Ru alloys indicates their formation from S-saturated magma, which is typical of tholeiite melts.
(2) The formation temperatures of magmatic PGM–chromite association are estimated at 1000–1200 °C. The temperatures of olivine–spinel equilibrium, reflecting the formation of chromitites and tectonic deformation processes, range from 1000 to 740 °C, and the log oxygen fugacity f(O2) is low, ranging from (−0.76) to (−4.4), which indicates the upper mantle conditions, as well as the effect of reduced mantle fluids.
(3) Platinum-group mineralization in the Ulan-Sar’dag chromitites reflects a long history of formation and transformation, a change in the fluid conditions from magmatic to metamorphic ones. Primary PGMs (Os-Ir-Ru alloys-I, laurite I) were formed under the condition of a high fugacity of sulfur. The physical–chemical conditions were as follows: T < 1200–1300 °C, and log f(S2) > (−2)/(−1). Under the influence of reduced fluids on chromitites, the desulfurization of laurite and the formation of secondary PGMs (native Os and Ru, Os-Ir-Ru alloys-II, laurite III, IrAsS, and RhNiAs) occur in association with serpentine, chlorite, nickel sulfides and arsenides. This association can be formed at T = 300–700 °C, log f(S2) = (−20), and P = 0.5 kbar.
(4) At the stage of ophiolite obduction and exposure to a metamorphogenic fluid, especially osmium, a further redistribution of PGE occurs. New phases of a non-stoichiometric composition (PGE + Cu, Te, Ba, As, Sb, O, and Cl) are formed. During progressive metamorphism, an enlargement and agglomeration of PGE nanoparticles to the microlevel occur.

Author Contributions

Conceptualization, O.N.K. and E.V.A.; methodology, D.K.B.; software, D.K.B. and E.V.A.; validation, S.M.Z. and E.V.A.; formal analysis, O.N.K.; investigation, O.N.K. and E.V.A.; resources, O.N.K. and S.M.Z.; data curation, O.N.K.; writing—original draft preparation, O.N.K. and E.V.A.; writing—review and editing, O.N.K., S.M.Z. and E.V.A.; visualization, E.V.A. and D.K.B.; supervision, S.M.Z.; project administration, O.N.K.; funding acquisition, O.N.K. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Ministry of Science and Higher Education of the Russian Federation and Russian Fond Basic Research Grant No. 16-05-00737a and 19-05-00764a. Work is done on state assignment of IGM SB RAS.

Acknowledgments

The work was carried out at the Analytical Center for multi-elemental and isotope research, SB RAS. The authors are grateful of I. Ashchepkov for constructive comments and suggestions when preparing an article.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Geological map of the southeastern part of the Eastern Sayan region [31]. NB—northern branch, SB—southern branch.
Figure 1. Geological map of the southeastern part of the Eastern Sayan region [31]. NB—northern branch, SB—southern branch.
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Figure 2. Geological scheme of the Ulan-Sar’dag ophiolite [39] with author additions.
Figure 2. Geological scheme of the Ulan-Sar’dag ophiolite [39] with author additions.
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Figure 3. Photographs of the field relationship between mantle peridotites and volcanic-sedimentary rocks (Ilchir suite), limestone thickness (Irkut suit), Gargan gneisses, and Susunur tonalities: (a) view of the south side of the Ulan-Sar’dag ophiolite, (b) view of the north side of the Ulan-Sar’dag ophiolite.
Figure 3. Photographs of the field relationship between mantle peridotites and volcanic-sedimentary rocks (Ilchir suite), limestone thickness (Irkut suit), Gargan gneisses, and Susunur tonalities: (a) view of the south side of the Ulan-Sar’dag ophiolite, (b) view of the north side of the Ulan-Sar’dag ophiolite.
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Figure 4. Structural features of chromitite pods: (a) chromitite seams in dunites; (b) schlieren; (c) massive pods; (d) transformation of the schlieren type into the massive type due to deformation processes; (e) folded schlieren-type chromitites; (f) structure of the “snowball”.
Figure 4. Structural features of chromitite pods: (a) chromitite seams in dunites; (b) schlieren; (c) massive pods; (d) transformation of the schlieren type into the massive type due to deformation processes; (e) folded schlieren-type chromitites; (f) structure of the “snowball”.
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Figure 5. Accessory mineral association in chromitites. Hzl—heazlewoodite Ni3S2; Mlr—millerite NiS; Pn—pentlandite (Fe,Ni)9S8; Cv—covellite CuS; Cct—chalcocite Cu2S; Orc—orcelite Ni5As2; Mh—maucherite Ni11As8; Sct—scutterudite Co4(As4)3; Apy—arsenopyrite FeAsS; Sp—sphalerit ZnS; Gn—galena PbS; Au0, Cu0, Bi0—native gold, copper and bismuth.
Figure 5. Accessory mineral association in chromitites. Hzl—heazlewoodite Ni3S2; Mlr—millerite NiS; Pn—pentlandite (Fe,Ni)9S8; Cv—covellite CuS; Cct—chalcocite Cu2S; Orc—orcelite Ni5As2; Mh—maucherite Ni11As8; Sct—scutterudite Co4(As4)3; Apy—arsenopyrite FeAsS; Sp—sphalerit ZnS; Gn—galena PbS; Au0, Cu0, Bi0—native gold, copper and bismuth.
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Figure 6. Classification diagram of chrome spinels from the chromitites of Ulan-Sar’dag, based on the structural formula of spinels. Composition fields: I—chromite; II—alumo-chromite; III—chrome picotite; IV—subferrichromite; V—subferrialumochromite; VI—ferrichromite; VII—subferrialumoferrichromite; VIII—chrome magnetite; IX—subalumochrome magnetite; X—magnetite [40]. Notes: 1—chrome spinels-I; 2—chrome spinels-II; 3—chrome spinels-III; 4—chrome spinels-II, with inclusions (Os,Ru)S2; 5—chrome spinels-II, with olivine inclusion.
Figure 6. Classification diagram of chrome spinels from the chromitites of Ulan-Sar’dag, based on the structural formula of spinels. Composition fields: I—chromite; II—alumo-chromite; III—chrome picotite; IV—subferrichromite; V—subferrialumochromite; VI—ferrichromite; VII—subferrialumoferrichromite; VIII—chrome magnetite; IX—subalumochrome magnetite; X—magnetite [40]. Notes: 1—chrome spinels-I; 2—chrome spinels-II; 3—chrome spinels-III; 4—chrome spinels-II, with inclusions (Os,Ru)S2; 5—chrome spinels-II, with olivine inclusion.
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Figure 7. Photographs of chromitites with different values of IPGE/PPGE: (a) schlieren densely disseminates in serpentinizated dunite (∑PGE = 903ppb, and IPGE/PPGE = 0.03); (b) massive (∑PGE = 615 ppb, and IPGE/PPGE = 2.15).
Figure 7. Photographs of chromitites with different values of IPGE/PPGE: (a) schlieren densely disseminates in serpentinizated dunite (∑PGE = 903ppb, and IPGE/PPGE = 0.03); (b) massive (∑PGE = 615 ppb, and IPGE/PPGE = 2.15).
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Figure 8. Diagram of the compositions of PGE minerals: (a) Os-Ir-Ru alloys; (b) Laurite-erlichmanite: Lr I—primary, inclusion in chrome spinels or isolated grains, laurite II—primary altered sulfides, and laurite III—secondary sulfides. The fields shown in the diagrams are drawn from [41].
Figure 8. Diagram of the compositions of PGE minerals: (a) Os-Ir-Ru alloys; (b) Laurite-erlichmanite: Lr I—primary, inclusion in chrome spinels or isolated grains, laurite II—primary altered sulfides, and laurite III—secondary sulfides. The fields shown in the diagrams are drawn from [41].
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Figure 9. Back Scattered Electron (BSE) images of primary PGM, showing the textural and morphological relations of single and polyphase PGM from the Ulan-Sar’dag chromitites: (a) inclusion euhedral Os-Ir-Ru alloy—I in chromite, an. 1; (b) individual single-grain Os-Ir-Ru alloys—I, with a dissolution microstructure, an. 2; (c) inclusion in Cr-spinel of intergrowth laurite I and hornblende, an. 6; (d) individual grain of laurite I, an. 7; (e) grain of laurite II (an. 8), with inclusions of micro particle Os-Ir-Ru alloys—II; (f) grain laurite II (an. 9), associated with an unnamed phase (Ru,Ni,Os,Ir,Rh)AsS (an. 36) (laurite II is surrounded by Os-poor laurite, which grows with millerite); (g) substitution of laurite II by irarsite (an. 32), with remnants of laurite II (an. 10,11) and Os-Ir-Ru alloys—II; (h) laurite II (an. 12) surrounded by irarsite (an. 33). Abbreviations: Crsp—chrome spinel; Lr—laurite; Mlr—millerite. Notes: an. No—No analysis, as shown in Table 4.
Figure 9. Back Scattered Electron (BSE) images of primary PGM, showing the textural and morphological relations of single and polyphase PGM from the Ulan-Sar’dag chromitites: (a) inclusion euhedral Os-Ir-Ru alloy—I in chromite, an. 1; (b) individual single-grain Os-Ir-Ru alloys—I, with a dissolution microstructure, an. 2; (c) inclusion in Cr-spinel of intergrowth laurite I and hornblende, an. 6; (d) individual grain of laurite I, an. 7; (e) grain of laurite II (an. 8), with inclusions of micro particle Os-Ir-Ru alloys—II; (f) grain laurite II (an. 9), associated with an unnamed phase (Ru,Ni,Os,Ir,Rh)AsS (an. 36) (laurite II is surrounded by Os-poor laurite, which grows with millerite); (g) substitution of laurite II by irarsite (an. 32), with remnants of laurite II (an. 10,11) and Os-Ir-Ru alloys—II; (h) laurite II (an. 12) surrounded by irarsite (an. 33). Abbreviations: Crsp—chrome spinel; Lr—laurite; Mlr—millerite. Notes: an. No—No analysis, as shown in Table 4.
Minerals 10 00141 g009
Minerals 10 00141 g010 550
Figure 10. BSE images of secondary PGMs, showing the textural, morphological relations and assemblages of the PGM from the Ulan-Sar’dag chromitites: (a) intergrowth of laurite III (an. 26) and PGE bearing chalcocite Cu2S, with micro inclusions of Os-Ir-Ru alloys- II (an. 18); (b) polyphase aggregate of agglomeration PGM particles, consisting of Os-rich laurite III (an.28), native Os0 (an. 20), and Os-poor laurite III (an. 27); (c) composite grain of irarsite (an. 34), laurite III (an. 29), and unnamed phases (Ru, Ir, Te, Ni, S, O) within the interstitial chlorite of chromitites; (d) polyphase aggregate, consisting of Os-Ir-Ru alloys-II (an. 21), Ru0 (an. 22), zaccarinite RhNiAs (an. 35), and heazlewoodite. Abbreviations: Chl—chlorite; Cct—chalcocite; Hzl—heazlewoodite; Irs—irarsite; Lr III—laurite III. Notes: an. No—No analysis, as shown in Table 4.
Figure 10. BSE images of secondary PGMs, showing the textural, morphological relations and assemblages of the PGM from the Ulan-Sar’dag chromitites: (a) intergrowth of laurite III (an. 26) and PGE bearing chalcocite Cu2S, with micro inclusions of Os-Ir-Ru alloys- II (an. 18); (b) polyphase aggregate of agglomeration PGM particles, consisting of Os-rich laurite III (an.28), native Os0 (an. 20), and Os-poor laurite III (an. 27); (c) composite grain of irarsite (an. 34), laurite III (an. 29), and unnamed phases (Ru, Ir, Te, Ni, S, O) within the interstitial chlorite of chromitites; (d) polyphase aggregate, consisting of Os-Ir-Ru alloys-II (an. 21), Ru0 (an. 22), zaccarinite RhNiAs (an. 35), and heazlewoodite. Abbreviations: Chl—chlorite; Cct—chalcocite; Hzl—heazlewoodite; Irs—irarsite; Lr III—laurite III. Notes: an. No—No analysis, as shown in Table 4.
Minerals 10 00141 g010
Minerals 10 00141 g011 550
Figure 11. Plot of Pd/Ir versus Pt/Pt* for mantle peridotite and chromitites of the USO. The Pt anomaly is calculated as follows: Pt/[Pt]* = (Pt/8.3) × ( Rh / 1.6 ) × ( Pd / 4.4 ) [8]. US—Ulan-Sar’dag ophiolite; ophiolite complexes from around the world: I—Wadi Al Hwanet ophiolite, Saudi Arabia [47]; II—Oman ophiolite, Semail [48]; III—Veria ophiolite, Greece [49]; IV—Shetland Ophiolite Complex, Scotland [50]; V—Ray-Iz ophiolite, Russia [51].
Figure 11. Plot of Pd/Ir versus Pt/Pt* for mantle peridotite and chromitites of the USO. The Pt anomaly is calculated as follows: Pt/[Pt]* = (Pt/8.3) × ( Rh / 1.6 ) × ( Pd / 4.4 ) [8]. US—Ulan-Sar’dag ophiolite; ophiolite complexes from around the world: I—Wadi Al Hwanet ophiolite, Saudi Arabia [47]; II—Oman ophiolite, Semail [48]; III—Veria ophiolite, Greece [49]; IV—Shetland Ophiolite Complex, Scotland [50]; V—Ray-Iz ophiolite, Russia [51].
Minerals 10 00141 g011
Minerals 10 00141 g012 550
Figure 12. OSMA (olivine-spinel mantle array) is a spinel peridotite restite trend [52]. The chrome spinels are from: 1–4—the Ospa-Kitoy ophiolite: 1—dunites; 2—harzburgites; the chromitites are from: 3—the north-branch Ospa-Kitoy, 4—south-branch Ospa-Kitoy; 5—Ulan-Sar’dag ophiolite. Mg′-Mg/(Mg + Fe) in olivine; Cr′-Cr/(Cr + Al + Fe3+) in chrome spinel.
Figure 12. OSMA (olivine-spinel mantle array) is a spinel peridotite restite trend [52]. The chrome spinels are from: 1–4—the Ospa-Kitoy ophiolite: 1—dunites; 2—harzburgites; the chromitites are from: 3—the north-branch Ospa-Kitoy, 4—south-branch Ospa-Kitoy; 5—Ulan-Sar’dag ophiolite. Mg′-Mg/(Mg + Fe) in olivine; Cr′-Cr/(Cr + Al + Fe3+) in chrome spinel.
Minerals 10 00141 g012
Minerals 10 00141 g013 550
Figure 13. Plots of relations: (a) Al2O3_Crsp–Al2O3_melt; (b) TiO2_Crsp–TiO2_melt; (c) Al2O3_Crsp–Al2O3_melt; (d) calculated abundance of Al2O3–TiO2 in melt, as in the equilibrium with the Cr spinels from the chromitites of the USO and the chrome spinels of chromitites from all over the world. The fields for the chrome spinels of boninites [72,73,74], Troodos boninites [75,76], Thetford boninites [77] and MORB [78,79,80] are shown for comparison.
Figure 13. Plots of relations: (a) Al2O3_Crsp–Al2O3_melt; (b) TiO2_Crsp–TiO2_melt; (c) Al2O3_Crsp–Al2O3_melt; (d) calculated abundance of Al2O3–TiO2 in melt, as in the equilibrium with the Cr spinels from the chromitites of the USO and the chrome spinels of chromitites from all over the world. The fields for the chrome spinels of boninites [72,73,74], Troodos boninites [75,76], Thetford boninites [77] and MORB [78,79,80] are shown for comparison.
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Minerals 10 00141 g014 550
Figure 14. Tectonic discrimination diagrams: (a) Al2O3–Fe2+/Fe3+; (b) Mg′sp–Cr′sp; (c) Al2O3–TiO2 from the chromitites of the USO and chrome spinels of chromitites from all over the world. The chrome spinels’ composition fields for peridotites from different geodynamic settings are drawn from [18].
Figure 14. Tectonic discrimination diagrams: (a) Al2O3–Fe2+/Fe3+; (b) Mg′sp–Cr′sp; (c) Al2O3–TiO2 from the chromitites of the USO and chrome spinels of chromitites from all over the world. The chrome spinels’ composition fields for peridotites from different geodynamic settings are drawn from [18].
Minerals 10 00141 g014
Minerals 10 00141 g015 550
Figure 15. Diagrams: (a) PGE distribution in the Ulan-Sardag peridotite literature data [94]; (b) PGE distribution in the Ulan-Sar’dag peridotite author data; (c) PGE pattern of chromitites of ophiolite complexes from all over the world: The Wadi Al Hwanet ophiolite, Saudi Arabia [47]; Oman ophiolite, Semail [48]; Veria ophiolite, Greece [49]; Shetland Ophiolite Complex, Scotland [50]; Ray-Iz ophiolite, Russia [51]; Mongolian ophiolite [95]; 1—chromitites are enriched in Os-Ir-Ru; 2—chromitites are enriched in Pt-Pd; (d) PGE patterns in the Ulan-Sar’dag chromitites.
Figure 15. Diagrams: (a) PGE distribution in the Ulan-Sardag peridotite literature data [94]; (b) PGE distribution in the Ulan-Sar’dag peridotite author data; (c) PGE pattern of chromitites of ophiolite complexes from all over the world: The Wadi Al Hwanet ophiolite, Saudi Arabia [47]; Oman ophiolite, Semail [48]; Veria ophiolite, Greece [49]; Shetland Ophiolite Complex, Scotland [50]; Ray-Iz ophiolite, Russia [51]; Mongolian ophiolite [95]; 1—chromitites are enriched in Os-Ir-Ru; 2—chromitites are enriched in Pt-Pd; (d) PGE patterns in the Ulan-Sar’dag chromitites.
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Minerals 10 00141 g016 550
Figure 16. PGE assemblage (a) Ulan-Sar’dag chromitites; (b) the northern branch of the SEPES ophiolite; (c) the southern branch of the SEPES ophiolite [36].
Figure 16. PGE assemblage (a) Ulan-Sar’dag chromitites; (b) the northern branch of the SEPES ophiolite; (c) the southern branch of the SEPES ophiolite [36].
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Minerals 10 00141 g017 550
Figure 17. Scheme of the alteration and transformation of platinum-group minerals.
Figure 17. Scheme of the alteration and transformation of platinum-group minerals.
Minerals 10 00141 g017
Table
Table 1. Representative chemical composition of Cr spinels and the calculated parental melt composition (wt. %) of Cr spinels. Thermometric and oxybarometric data for Cr spinels.
Table 1. Representative chemical composition of Cr spinels and the calculated parental melt composition (wt. %) of Cr spinels. Thermometric and oxybarometric data for Cr spinels.
No.12345678910111213141516171819202122
I GroupII GroupIII Group
N Sample37417477101130132120104852475351128896071112218
TiO20.10.10.10.10.10.100.10.10.10.050.070.10.10.10.20.20.10.050.040.070.050.07
Al2O340.341.024.624.119.212.197.9715.314.613.5216.5314.514.813.912.512.414.614.613.014.016.519.6
Cr2O329.728.544.243.749.259.5763.9456.454.256.5153.7055.655.656.556.457.057.354.055.449.048.048.3
MnO0.50.50.20.30.3 0.30.30.320.560.30.40.30.50.40.40.30.40.40.70.3
FeO7.97.914.714.814.415.419.113.314.815.815.315.416.415.616.116.317.719.018.318.620.919.8
Fe2O32.02.32.12.63.32.40.71.22.11.72.11.62.31.72.72.71.11.82.35.65.82.5
MgO19.719.813.613.312.912.610.813.712.411.712.412.011.711.911.411.310.99.69.89.68.39.6
V2O50.80.80.10.10.1 0.10.10.13 0.1 0.10.10.10.10.10.070.110.120.09
NiO0.30.30.20.10.0 0.00.10.02 0.0 0.00.00.00.10.00.030.060.070.02
ZnO0.00.00.00.20.7 0.00.00.14 0.1 0.20.30.20.00.30.190.100.460.46
Total101.3101.199.899.2100.2102.3234.6100.498.699.8100.799.7101.2100.2100.1100.5102.299.899.597.6100.9100.7
Al’56573534272326202019232020192020202018202328
Cr′41406262697484808079748080808080808078716869
Fe′2.7333.742.90.91.73.02.32.92.23.22.33.73.71.62.63884
Mg′72714847475950495457555658575959626635342933
f′28295253534150495457555658575959626665667167
TiO2melt0.10.10.10.10.10.180.110.10.20.100.130.10.10.10.40.30.20.100.090.140.100.14
Al2O3 melt18.318.515.014.913.511.19.312.312.211.712.712.112.111.811.311.312.012.111.512.012.713.6
(Fe/Mg)m0.30.30.50.60.50.50.70.40.50.60.50.60.60.60.60.60.70.90.780.801.070.96
T°C (Ol-Sp)919.1893.9823.4820.7885.7938.62991.61003.9948.9931.8891.6931.5921.2933.2942.4913.6861.2812.6846.3821742.7738.1
fO2−0.988−0.765−1.498−1.246−1.1−2.48−1.3−2.1−1.3−1.8−2.5−1.9−1.6−1.9−1.1−2.8−4.4−3.3−3.01−1.49−1.73−2.78
T°C (Al in Ol) 893–1332 1073–1225
Notes: Al′ = Al/(Al + Cr + Fe3+); Cr′ = Cr/(Cr + Al + Fe3+); Fe′ = Fe3+/(Cr + Al + Fe3+); Mg′ = Mg/(Mg + Fe2+); f′ = Fe2+/(Mg + Fe2+); Sample No. 1–5—Cr-spinels I; 6–18—Cr-spinels II; 19–22—Cr-spinels III; T°C (Ol-Sp)—olivine-spinel geothermometer; f(O2)—oxygen fugacity; T°C (Al in Ol)—olivine geothermometer.
Table
Table 2. Chemical composition of the olivine from chromitites (wt. %).
Table 2. Chemical composition of the olivine from chromitites (wt. %).
N-SampleSiO2MgOFeONiOMnOCaOAl2O3Cr2O3TotalMg#
298-141.2852.594.980.410.110.001 0.00299.3895
298-241.8352.254.500.420.090.001 0.00299.0895
298-341.2652.205.680.420.120.002 0.00499.6894
298-441.3152.105.710.420.130.0010.01180.00299.6894
298-541.4152.685.340.440.110.0020.00520.00299.9895
3-641.0851.196.950.370.110.0010.01910.00299.7393
3-741.1051.046.980.370.110.00300.00199.6093
3-841.1551.036.850.380.120.0040.0119099.5493
3-940.8350.857.130.380.130.0150.01040.00299.3493
3-1041.1351.176.920.380.100.0030.0015099.6993
3-1141.2251.026.890.370.110.0040.01170.00199.6293
3-1241.0951.166.900.380.130.0060.00050.00199.6693
3-1341.0751.196.890.370.130.0050.0006 99.6593
3-1441.1051.086.930.370.100.0060.0009 99.5893
3-1541.2451.266.790.380.130.0090.0030.00299.8093
305-1641.3353.613.28 0.6198.8397
305-1741.3853.863.45 0.6999.3897
2-1841.0551.716.47 99.2393
973-1940.2550.248.14 0.0198.6492
976-2041.4351.266.90 0.0299.6193
977-2140.0950.396.85 0.02 0.0097.3593
939-2240.9449.597.28 0.01 0.0397.8592
939-2340.7449.069.61 0.04 0.3699.8190
970-2440.8549.937.87 0.00 0.0298.6792
980-2542.3953.595.50 0.01 0.02101.5195
Notes: (Samples 16–18)—inclusions in chromite.
Table
Table 3. PGE abundance for the dunites and chromitites of the Ulan-Sar’dag ophiolite (ppb).
Table 3. PGE abundance for the dunites and chromitites of the Ulan-Sar’dag ophiolite (ppb).
No.1234567891011
N Sample63056 mas7 mas294 mas307 mas6 mas3 mas17 mas20 mas2 shl
Os68455158117493781467
Ir21626584382572035206
Ru714685311622112159444620
Rh731210819241691121
Pt3515394931544964464135
Pd10448177182104122478978778903
Total18094367403360615778293302242992
Pt/Ir1.672.51.50.840.720.660.863.201.312.055.83
∑IPGE342813916221742022711616011233
∑PPGE14666228241143195551177142130959
IPGE/PPGE0.230.420.610.671.522.150.410.661.130.860.03
∑PGE18094367403360615778293302242992
Cr# (Crt) 686765577069848375
Al#(Crt) 303042342627141522
Notes: 1,2—dunites; 3–11—chromitites. mas—massive pods, shl—shlieren pods; 3–6—group I chromitites; 7–10—group II chromitites; 11—group III chromitite.
Table
Table 4. Representative composition of platinum-group elements in the chromitite from the Ulan-Sar’dag ophiolitic massif.
Table 4. Representative composition of platinum-group elements in the chromitite from the Ulan-Sar’dag ophiolitic massif.
No. anOsIrRuRhFeNiSAsSbOTotalOsIrRuRhFeNiSAsSbORu/
(Ru + Os)
wt. % apfu
175.0121.953.38 0.72 101.060.390.110.03 0.01
274.8420.65.16 0.33 0 100.930.390.110.05 0.01
379.7520.742.35 0.35 103.190.410.10.02 0.01
423.875.2334.23 0.59 33.36 97.280.240.050.65 0.02 2 0.59
523.215.1839.550.6 34.33 102.870.230.050.730.010.00 2 0.63
633.295.527.26 0.58 31.27 97.90.360.060.55 0.02 2 0.45
722.924.339.85 35.23 102.30.220.050.73 2 0.63
820.656.8639.48 33,15 100.140.210.070.75 2 0.66
98.945.7650.87 37.82 103.390.080.050.85 2 0.85
1033.622.9334.3 320.66 103.510.350.030,67 1.980.02 0.51
1149.972.1820.8 30.12 103.070.560.020.44 2.00 0.29
12 3.558.59 38.191.67 101.95 0.030.95 1.960.04 1
13 62.81 39.43 102,24 1.01 2 1
141.914.4557.45 0,320.4936.310.92 101,850.020.040,99 0,010.011.980.02 0.97
1592.7308.57 0.471.20.19 103.160.79 0.14 0,000.010.06
1637.9831.1729.55 0.881.61 101.190.290.230.42 0.020.04
1728.7927.2937.064.40.71 1.15 99.40.210.20.510.060.02
1833.3311.1953.61 2.12100.250.190.060.6 0.14
1934.259.5154.3 1.57 3.19102.820.170.050.54 0.05 0.19
2088.0111.34 1.092.01 0.2 0.66103.310.80.1 0.030.06
2159.4616.7821.62 0.583.06 101.50.460.130.32 0.010.07
222.522.1193.14 2.55 100.320.010.010.93 0.04
233.013.6752.84 0.9936.783.3 100.590.030.030.88 0.031.930.07 0.95
24 60.54 0.320.4638.33 99.65 1 0.010.012 1
2547.444.9722.55 0.37 27.28 102.610.590.060.52 0.02 2 0.32
26 60.93 38.64 99.57 1 2 1
279.253.4754.02 34.92 101.660.090.030.98 2 0.85
2860.286.176.88 0.371.0423.79 98.530.850.090.18 0.020.052 0.1
29 59.89 0.46 37.67 98.02 1.01 0.01 2 1
30 58.692.12.31 12.5123.25 98.86 0.290.020.02 0.370.30
311.1859.231.440.35 0.8111.3824.82 99.210.030.410.1 0.630.37
321.856.585.840.6 12.8519.071 97.740.010.290.060.01 0.390.250.01
33 48.2311.473.91 16.8120.93 101.35 0.210.090.03 0.440.23
34 61.042.530.87 11.8123.781.16 0.300.020.01 0.350.300.01
354.213.151037.77 22.35 25.66 103.140.020.010.080.3 0,31 0.28
3621.3410.5826.920.57 28.956.514.23 109.090.170.080.400.01 0.740.310.29
Notes: Primary high temperature PGM: Os-Ir-Ru alloys-I—(1–3); laurite I—(4–7); altered laurite II—(8–14); secondary PGM: Os-Ir-Ru alloys-II—(15–22); laurite III—(23–29); irarsite—(30–34); RhNiAs—35; (Ru,Ni,Os,Ir,Rh)AsS—36.
Table
Table 5. Chemical composition of Ni, Fe, and Cu sulfides and arsenides (wt. %).
Table 5. Chemical composition of Ni, Fe, and Cu sulfides and arsenides (wt. %).
No.
Mineral 		2a-12
(Fe,Ni)9S8		6-12
Cu2S		6-13
Ni3S2		3-13
NiS		6-13
Ni3S2		4-12
Ni3S2		3-13
Ni3As2
Ni38.9 67.564.1672.8272.1964.24
Fe25.58
Cu 64.89
Co0.87
Os 4.34
Ir 1.18
Ru 8.015.29
Rh 0.42
S33.0819.825.8133.8227.2527.2
As 0.55 36.01
O 1.06
Total98.4399.2899.5797.98100.0799.39100.25
Incl. in olivinePGE bearing, intergrowth with PGMPGE-free, individual grains
Table
Table 6. Calculated parental melt composition of chrome spinels.
Table 6. Calculated parental melt composition of chrome spinels.
Cr-Spinels Al′Cr#′Mg′Parental Melt (wt. %)References
1I group24–6036–7445–74Al2O3, 13–18; TiO2, 0–0.14
FeO/MgO, 0.2–0.7		In this article
2II group14–2374–8132–48Al2O3, 10–12; TiO2, 0–0.35
FeO/MgO, 0.4–0.85		In this article
3III group13–2768–8128–35Al2O3, 10–13; TiO2, 0.08–0.13
FeO/MgO, 0.7–1		In this article
4Ospa-Kitoy medium Al′24-–4159–7543–70Al2O3, 12–14; TiO2, 0.01–0.44
FeO/MgO, 0.5–1.1		[38]
5Ospa-Kitoy low Al′9–2177–9023–59Al2O3, 8–11; TiO2, 0.01–0.48
FeO/MgO, 0.5–2.4		[38]
6MORB35–6429–5757–59Al2O3 13–18; TiO2, 0.3–1.7
FeO/MgO, 0.5–0.7		[18,69];
7BAB613475Al2O3, 17.6; TiO2, 0.4
FeO/MgO, 0.4		[18]
8OIB286157Al2O3, 12; TiO2, 1.6
FeO/MgO, 0.6		[18]
9IAB15–2961–6858–69Al2O3, 9–12; TiO2, 0.4–0.7
FeO/MgO, 0.3–0.5		[18]
10IABon, IAT5–1974–8958–75Al2O3, 6–10; TiO2, 0.08–0.4
FeO/MgO, 0.2–0.4		[18]
11LIP13–3552–7235–61Al2O3, 8–13; TiO2, 0.2–0.5
FeO/MgO, 0.4–1.2		[18]
12Abissal peridotite45–7720–5064–77Al2O3, 15–19; TiO2, 0.08–0.1
FeO/MgO, 0.4–0.5		[70]
13Chromite in ophiolite mantle40–5144–5263–74Al2O3, 14–16; TiO2, 0.2–0.5
FeO/MgO, 0.3–0.6		[3]
14Chromite in ophiolite mantle21–2867–7456–68Al2O3, 10–12; TiO2, 0.1–0.3
FeO/MgO, 0.54–0.6		[3,48]
15Chromite in Alaskan type11–1462–7045–56Al2O3, 8–9; TiO2, 0.6–0.9
FeO/MgO, 0.4–0.5		[71]

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Kiseleva, O.N.; Airiyants, E.V.; Belyanin, D.K.; Zhmodik, S.M. Podiform Chromitites and PGE Mineralization in the Ulan-Sar’dag Ophiolite (East Sayan, Russia). Minerals 2020, 10, 141. https://doi.org/10.3390/min10020141

AMA Style

Kiseleva ON, Airiyants EV, Belyanin DK, Zhmodik SM. Podiform Chromitites and PGE Mineralization in the Ulan-Sar’dag Ophiolite (East Sayan, Russia). Minerals. 2020; 10(2):141. https://doi.org/10.3390/min10020141

Chicago/Turabian Style

Kiseleva, Olga N., Evgeniya V. Airiyants, Dmitriy K. Belyanin, and Sergey M. Zhmodik. 2020. "Podiform Chromitites and PGE Mineralization in the Ulan-Sar’dag Ophiolite (East Sayan, Russia)" Minerals 10, no. 2: 141. https://doi.org/10.3390/min10020141

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