Ore Genesis of the Takatori Tungsten–Quartz Vein Deposit, Japan: Chemical and Isotopic Evidence

Morishita, Y.; Nishio, Yoshiro

doi:10.3390/min11070765

Cited by 7 publications

(4 citation statements)

References 25 publications

(80 reference statements)

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“…This is inconsistent with a magmatic origin, suggesting instead a shear-zone induced hydrothermal system with meteoric water [22]. Even if there was early-stage magmatic fluid for the Takatori hypothermal tungsten-quartz vein deposit in Japan, the δ 18 O value of the fluid decreased with decreasing temperature because the fluid was mixed with meteoric water [23].…”

Section: Carbon and Oxygen Isotope Ratios Of Calcite From The Kamioka Mining Districtmentioning

confidence: 93%

Role of Hydrothermal Fluids in the Formation of the Kamioka Skarn-Type Pb–Zn Deposits, Japan

Morishita

Wada

2021

Geosciences

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The Kamioka mine, located in Gifu Prefecture in Japan, is famous for the large water Cherenkov detector system, the Super-Kamiokande. The Kamioka skarn-type Pb–Zn deposits are formed in crystalline limestone and are replaced by skarn minerals within the Hida metamorphic rocks. The Kamioka deposits mainly consist of the Tochibora, Maruyama, and Mozumi deposits. The present study focuses on the ore-forming hydrothermal fluid activity in the Kamioka deposits and the peripheral exploration area based on the carbon and oxygen isotope ratios of calcite and rare earth element (REE) analyses. The carbon and oxygen isotope ratios of crystalline limestone (as the host rock) are not homogeneous, and depending on the degree of hydrothermal activity, they decreased to various degrees because of the reaction with the ore fluids. Thus, the carbon and oxygen isotope ratios of crystalline limestone can be used as an indicator of the influence of the hydrothermal fluids for the ore mineralization. The REE contents in the ores of igneous origin are one order of magnitude higher than the limestone origin. Further, depending on the formation temperatures, calcites precipitated during ore mineralization have a stable carbon isotope ratio and a widely varying oxygen isotope ratios. The Kamioka district fracture system is likely a major control factor on ore mineralization from hydrothermal activity. In addition, the skarnization-related ore-forming fluids are mostly meteoric in origin, confirming the conclusions from previous studies.

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Section: Carbon and Oxygen Isotope Ratios Of Calcite From The Kamioka Mining Districtmentioning

confidence: 93%

Role of Hydrothermal Fluids in the Formation of the Kamioka Skarn-Type Pb–Zn Deposits, Japan

Morishita

Wada

2021

Geosciences

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“…The relationships between equilibrium and kinetics from the previous oxygen isotopic studies on hydrothermal ore deposits are discussed in the second half. Several isotopic studies (Kushikino deposit [22,29], Ohtani and Kaneuchi deposits [24], Takatori deposit [25], and Noya deposit [26]) were introduced, assuming that the mineral assemblages were close to equilibrium. We observed varying degrees of kinetic reactions and equilibrium goals in the δ 13 C-δ 18 O relationship of limestone at the Kamioka deposit [27].…”

Section: Discussionmentioning

confidence: 99%

“…The following estimations of the oxygen isotope equilibrium temperatures of the mineral-pair formation were used as an oxygen isotope thermometer based on the isotopic equilibrium for the mineral-pair: a quartz-muscovite thermometer for tungstenquartz vein deposits (Ohtani and Kaneuchi deposits [24]), quartz-wolframite and quartzcassiterite thermometers for tungsten-quartz vein deposits (Takatori deposit [25]), and a quartz-calcite thermometer for gold-bearing quartz-calcite veins (Noya deposit [26]).…”

Section: Hydrothermal Depositmentioning

confidence: 99%

Hydrothermal Calcite Precipitation in Veins: Inspired by Experiments for Oxygen Isotope Fractionation between CO2 and Calcite from 1 °C to 150 °C

Morishita

2023

Applied Sciences

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The oxygen isotope ratios of minerals are important for estimating the formation temperature of hydrothermal deposits. Calcite is generally found in most mining districts. The oxygen isotope ratio of hydrothermal calcite in isotopic equilibrium with a fluid depends on that of the fluid as well as the formation temperature. The isotope ratios of calcite are generally determined to measure the isotope ratios of CO2 generated via reaction with 100% phosphoric acid at 25 °C. This is why the oxygen isotope fractionation between CO2 and calcite at 25 °C is required to conduct the procedure. When using other carbonate minerals such as dolomite, ankerite, and siderite, the reaction requires higher temperatures. Therefore, the oxygen isotope fractionation between CO2 and calcite at higher temperatures should be known because the laboratory standard sample of carbonates is usually calcite. Here, the oxygen isotope fractionation in CO2 during the reaction of calcite with phosphoric acid at temperatures between 1 °C and 150 °C was thoroughly determined in the first half, and the value can be represented by the following equation: 1000 lnα = 0.494 (106/T2) + 4.64. The experiments raised questions such as the equilibrium vs. kinetics issue in isotopic reactions in the formation of hydrothermal ore deposits. The raised issue is discussed in the second half based on the findings of previous isotope studies in deposits.

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“…The δD fluid values for samples KR-4 and KR-5 are very similar to the δD values of altered granites from the Bohemian Massif (Figure 17). Based on oxygen isotopes, the participation of both magmatic and meteoric fluids during the formation of quartz veins with Sn-W mineralization was also reported [69] from the Takatori deposit in Japan. [68], granites from Horní Slavkov-Hub Stock [17] and Cínovec [14], greisens from Iberian Central system [70], greisen cassiterite mineralization from Uljin Area [71], greisens from New Ross area in Canada [72], Sn-W mineralization, Mawchi, Myanmar [73], and unpublished data by M. René for topaz-albite granites of the Bohemian Massif.…”

Section: Origin Of Fluidsmentioning

confidence: 94%

Fluid Evolution of Greisens from Krupka Sn-W Ore District, Bohemian Massif (Czech Republic)

Krejčí Kotlánová,

Dolníček,

René

et al. 2024

Minerals

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The Sn-W ore deposits in the Krupka surroundings are associated with greisens, which occur in the upper parts of Late Variscan granitoid intrusions. Fluid inclusions were studied in samples of quartz, cassiterite, apatite, fluorite, and topaz in greisenized granites, greisens, and hydrothermal veins with Sn-W mineralization. The greisenization process took place at temperatures 370–490 °C and pressures 155–371 bars, and associated fluids had predominantly low salinity and a low gas (CO2, N2 and CH4) content. The post-greisenization stage was connected with the formation of (i) low-salinity (0–8 wt. % NaCl eq.) fluid inclusions with homogenization temperatures <120–295 °C and (ii) high-salinity (18 to >35 wt. % NaCl eq.) fluid inclusions with homogenization temperatures 140–370 °C, often containing trapped crystals of quartz, topaz, and sulfides, or daughter crystals of salts and carbonates, which were identified by microthermometric measurements, electron microprobe analysis, and Raman spectroscopy. Analyses of fluid inclusion leachates have shown that Na and Ca chlorides predominate in fluids. According to hydrogen stable isotopes, the source of greisenizing and post-greisenizing fluids was not only magmatogenic but also meteoric water or fluids derived from sedimentary rocks.

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Ore Genesis of the Takatori Tungsten–Quartz Vein Deposit, Japan: Chemical and Isotopic Evidence

Cited by 7 publications

References 25 publications

Role of Hydrothermal Fluids in the Formation of the Kamioka Skarn-Type Pb–Zn Deposits, Japan

Role of Hydrothermal Fluids in the Formation of the Kamioka Skarn-Type Pb–Zn Deposits, Japan

Hydrothermal Calcite Precipitation in Veins: Inspired by Experiments for Oxygen Isotope Fractionation between CO2 and Calcite from 1 °C to 150 °C

Fluid Evolution of Greisens from Krupka Sn-W Ore District, Bohemian Massif (Czech Republic)

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