Isotopic and geochemical study of the conditions of tin ore formation of Solnechnoye deposit(Far East of Russia).

Abstract: Physical chemical characteristics of the Solnechnoye tin deposit hydrothermal system have been stud ied. Ores of cassiterite-tourmaline type was formed in a vertically dipping fracture zone, extended up to 8 km in a metamorphosed mass of sandstone-shale rocks. This rock mass transfers in its root part to a granitoid massif (quartz diorites-monzonites).The evolution in composition of the mineral-forming solution was studied by gas-chromatographic analysis of gaseous phase of fluid inclusions. The analysis of aq… Show more

“…The change of mineral assemblages of these stages shows that early sodium chloride fluids gave way to dilute, alkaline bicarbonate–chloride–fluoride fluids. This was interpreted by Bannikova et al ., (1994) as a possible result of the mixing of exogenic waters of meteoric origin into the ore‐forming system. The fluid inclusion studies of Radkevich et al .…”

“…The higher range of δ 18 O compositions of fluids in tourmalines from the Glavnaya and Pridorozhnaya ore zones, compared to those from the Avral and Levosilin barren zones, is likely to be due to interaction of magmatic fluid with wallrocks (cf. Bannikova et al ., 1994). This process probably resulted in favorable physico‐chemical conditions that induced precipitation of cassiterite from the mineralizing fluids.…”

“…The fluid inclusion studies of Radkevich et al . (1967), Bannikova et al . (1994), and Bortnikov et al .…”

“…The quartz‐tourmaline metasomatite horizon overlies the granitoid and underlies quartz‐sericite metasomatic rocks and sericitized terrigenous sedimentary rocks. The mineralization of the deposit has been classified in four main stages (Radkevich et al ., 1967; Bannikova et al ., 1994). Stage 1 is a pre‐ore quartz‐tourmaline assemblage with accessory sericite, chlorite and topaz.…”

“…Physico‐chemical data describing transport and deposition of Sn in hydrothermal environments allow deduction of processes associated with the precipitation of cassiterite (SnO 2 ), such as fluid mixing, fluid heterogenization (boiling or immiscibility) and fluid interaction with wallrocks (Eugster, 1985; Heinrich, 1990; Sushchevskaya & Ryzhenko, 2002; Bortnikov et al ., 2005; Sushchevskaya et al ., 2006). Systematic studies of materials from large Sn and Sn–W deposits, such as Panasqueira in Portugal (Noronha et al ., 1999), Huanuni in Bolivia (Müller et al ., 2001), Brandberg West in Namibia (Macey & Harris, 2006), Svetloye, Khinganskoye, and Solnechnoye in Far East Russia (Bannikova et al ., 1994; Sushchevskaya et al ., 2000; Spasennykh et al ., 2002) helped to conclude that these deposits formed from magmatic fluids, which were mixed with meteoric waters, and interacted with the country rocks before the precipitation of ore minerals. Geochemical studies of Sn deposits in Russia (Ryzhenko et al ., 1998; Sushchevskaya & Ryzhenko, 2002) led to the conclusion that Sn deposits also formed by fluid‐rock interactions in hydrothermal systems where the mineralizing fluid was mainly magmatic and partly meteoric in origin.…”

Magmatic Nature of Mineralizing Fluids in the Solnechnoye Sn Deposit (Russia) Deduced from Isotopic (H, O) Compositions of Tourmaline

“…The change of mineral assemblages of these stages shows that early sodium chloride fluids gave way to dilute, alkaline bicarbonate–chloride–fluoride fluids. This was interpreted by Bannikova et al ., (1994) as a possible result of the mixing of exogenic waters of meteoric origin into the ore‐forming system. The fluid inclusion studies of Radkevich et al .…”

“…The higher range of δ 18 O compositions of fluids in tourmalines from the Glavnaya and Pridorozhnaya ore zones, compared to those from the Avral and Levosilin barren zones, is likely to be due to interaction of magmatic fluid with wallrocks (cf. Bannikova et al ., 1994). This process probably resulted in favorable physico‐chemical conditions that induced precipitation of cassiterite from the mineralizing fluids.…”

“…The fluid inclusion studies of Radkevich et al . (1967), Bannikova et al . (1994), and Bortnikov et al .…”

“…The quartz‐tourmaline metasomatite horizon overlies the granitoid and underlies quartz‐sericite metasomatic rocks and sericitized terrigenous sedimentary rocks. The mineralization of the deposit has been classified in four main stages (Radkevich et al ., 1967; Bannikova et al ., 1994). Stage 1 is a pre‐ore quartz‐tourmaline assemblage with accessory sericite, chlorite and topaz.…”

“…Physico‐chemical data describing transport and deposition of Sn in hydrothermal environments allow deduction of processes associated with the precipitation of cassiterite (SnO 2 ), such as fluid mixing, fluid heterogenization (boiling or immiscibility) and fluid interaction with wallrocks (Eugster, 1985; Heinrich, 1990; Sushchevskaya & Ryzhenko, 2002; Bortnikov et al ., 2005; Sushchevskaya et al ., 2006). Systematic studies of materials from large Sn and Sn–W deposits, such as Panasqueira in Portugal (Noronha et al ., 1999), Huanuni in Bolivia (Müller et al ., 2001), Brandberg West in Namibia (Macey & Harris, 2006), Svetloye, Khinganskoye, and Solnechnoye in Far East Russia (Bannikova et al ., 1994; Sushchevskaya et al ., 2000; Spasennykh et al ., 2002) helped to conclude that these deposits formed from magmatic fluids, which were mixed with meteoric waters, and interacted with the country rocks before the precipitation of ore minerals. Geochemical studies of Sn deposits in Russia (Ryzhenko et al ., 1998; Sushchevskaya & Ryzhenko, 2002) led to the conclusion that Sn deposits also formed by fluid‐rock interactions in hydrothermal systems where the mineralizing fluid was mainly magmatic and partly meteoric in origin.…”

Magmatic Nature of Mineralizing Fluids in the Solnechnoye Sn Deposit (Russia) Deduced from Isotopic (H, O) Compositions of Tourmaline

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