Details
Original language | English |
---|---|
Article number | 120438 |
Journal | Chemical geology |
Volume | 583 |
Early online date | 14 Jul 2021 |
Publication status | Published - 20 Nov 2021 |
Abstract
The Mo deposits from the Qinling-Dabie area, central China, which are characteristic for a new type of porphyry Mo deposits named the Collision-type, were formed in CO2-rich magmatic-hydrothermal environments. Yet the effects of CO2 on molybdenum transport and precipitation are still poorly known. To fill this gap and provide insight into the formation of Collision-type porphyry Mo deposit, we performed high pressure experiments to systematically quantify the role of CO2 on the solubility of molybdenum-bearing phases. Molybdenite was placed together with a single-phase H2O-CO2-NaCl fluid (8 wt% NaCl Eq.) at 600 °C and 200 MPa. The experiments were buffered by the pyrite-pyrrhotite-magnetite assemblage. At such conditions, combined microthermometric and LA-ICP-MS analysis of synthetic fluid inclusions reveals that the molybdenite solubility in the fluids coexisting with molybdenite decreases slightly (from 87 ± 17 ppm to 38 ± 13 ppm Mo) with increasing CO2 (from XCO2 = 0.10 to 0.25 M fraction). Such a Mo solubility is comparable to that determined in CO2-free fluids (61 ± 14 ppm) with the same salinity. At XCO2 = 0.33, fluid immiscibility is observed and Mo would partition preferentially into the brine phase, with a DMoliq/vap (=CMoliquid/CMovapor) value of 2.9 ± 1.0 (1σ). The evolution of molybdenite solubility with increasing CO2 in the fluid may be explained by changes of the dielectric constant of the solvent. Our results demonstrate that at the studied experimental temperature and pressure, CO2-rich fluids can transport comparable amounts of molybdenum as in H2O-dominated solutions. Combined with existing literature data over a broad range of pressure, temperature, and oxygen fugacity conditions, our data indicate that decreasing temperature and oxygen fugacity facilitate molybdenite precipitation. Albeit the nil-to-negative effect of CO2 on molybdenum solubility, the presence of CO2 would affect significantly fluid saturation of silicate melts. Notably, boiling is expected to occur at higher pressure in the presence of CO2, which may explain the deeper mineralization depth observed for the Collision-type porphyry molybdenum deposit.
Keywords
- Collision-type, HO-CO-NaCl fluid, Molybdenite solubility, Molybdenum partitioning, Porphyry molybdenum deposit
ASJC Scopus subject areas
- Earth and Planetary Sciences(all)
- Geology
- Earth and Planetary Sciences(all)
- Geochemistry and Petrology
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In: Chemical geology, Vol. 583, 120438, 20.11.2021.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Molybdenum solubility and partitioning in H2O-CO2-NaCl fluids at 600 °C and 200 MPa
AU - Li, Nuo
AU - Derrey, Insa T.
AU - Holtz, Francois
AU - Horn, Ingo
AU - Weyer, Stefan
AU - Xi, Wei
N1 - Funding Information: We appreciated the technical support from Dongmei Qi, Julian Feige, Ulrich Kroll and Andreas Reimer. Funding for this work was provided by the Alexander von Humboldt Foundation and National Natural Science Foundation of China (Nos. U1603341 and 41630313 ) and the Xinjiang Outstanding Youth Scientific Grant (No. 2020Q006 ).
PY - 2021/11/20
Y1 - 2021/11/20
N2 - The Mo deposits from the Qinling-Dabie area, central China, which are characteristic for a new type of porphyry Mo deposits named the Collision-type, were formed in CO2-rich magmatic-hydrothermal environments. Yet the effects of CO2 on molybdenum transport and precipitation are still poorly known. To fill this gap and provide insight into the formation of Collision-type porphyry Mo deposit, we performed high pressure experiments to systematically quantify the role of CO2 on the solubility of molybdenum-bearing phases. Molybdenite was placed together with a single-phase H2O-CO2-NaCl fluid (8 wt% NaCl Eq.) at 600 °C and 200 MPa. The experiments were buffered by the pyrite-pyrrhotite-magnetite assemblage. At such conditions, combined microthermometric and LA-ICP-MS analysis of synthetic fluid inclusions reveals that the molybdenite solubility in the fluids coexisting with molybdenite decreases slightly (from 87 ± 17 ppm to 38 ± 13 ppm Mo) with increasing CO2 (from XCO2 = 0.10 to 0.25 M fraction). Such a Mo solubility is comparable to that determined in CO2-free fluids (61 ± 14 ppm) with the same salinity. At XCO2 = 0.33, fluid immiscibility is observed and Mo would partition preferentially into the brine phase, with a DMoliq/vap (=CMoliquid/CMovapor) value of 2.9 ± 1.0 (1σ). The evolution of molybdenite solubility with increasing CO2 in the fluid may be explained by changes of the dielectric constant of the solvent. Our results demonstrate that at the studied experimental temperature and pressure, CO2-rich fluids can transport comparable amounts of molybdenum as in H2O-dominated solutions. Combined with existing literature data over a broad range of pressure, temperature, and oxygen fugacity conditions, our data indicate that decreasing temperature and oxygen fugacity facilitate molybdenite precipitation. Albeit the nil-to-negative effect of CO2 on molybdenum solubility, the presence of CO2 would affect significantly fluid saturation of silicate melts. Notably, boiling is expected to occur at higher pressure in the presence of CO2, which may explain the deeper mineralization depth observed for the Collision-type porphyry molybdenum deposit.
AB - The Mo deposits from the Qinling-Dabie area, central China, which are characteristic for a new type of porphyry Mo deposits named the Collision-type, were formed in CO2-rich magmatic-hydrothermal environments. Yet the effects of CO2 on molybdenum transport and precipitation are still poorly known. To fill this gap and provide insight into the formation of Collision-type porphyry Mo deposit, we performed high pressure experiments to systematically quantify the role of CO2 on the solubility of molybdenum-bearing phases. Molybdenite was placed together with a single-phase H2O-CO2-NaCl fluid (8 wt% NaCl Eq.) at 600 °C and 200 MPa. The experiments were buffered by the pyrite-pyrrhotite-magnetite assemblage. At such conditions, combined microthermometric and LA-ICP-MS analysis of synthetic fluid inclusions reveals that the molybdenite solubility in the fluids coexisting with molybdenite decreases slightly (from 87 ± 17 ppm to 38 ± 13 ppm Mo) with increasing CO2 (from XCO2 = 0.10 to 0.25 M fraction). Such a Mo solubility is comparable to that determined in CO2-free fluids (61 ± 14 ppm) with the same salinity. At XCO2 = 0.33, fluid immiscibility is observed and Mo would partition preferentially into the brine phase, with a DMoliq/vap (=CMoliquid/CMovapor) value of 2.9 ± 1.0 (1σ). The evolution of molybdenite solubility with increasing CO2 in the fluid may be explained by changes of the dielectric constant of the solvent. Our results demonstrate that at the studied experimental temperature and pressure, CO2-rich fluids can transport comparable amounts of molybdenum as in H2O-dominated solutions. Combined with existing literature data over a broad range of pressure, temperature, and oxygen fugacity conditions, our data indicate that decreasing temperature and oxygen fugacity facilitate molybdenite precipitation. Albeit the nil-to-negative effect of CO2 on molybdenum solubility, the presence of CO2 would affect significantly fluid saturation of silicate melts. Notably, boiling is expected to occur at higher pressure in the presence of CO2, which may explain the deeper mineralization depth observed for the Collision-type porphyry molybdenum deposit.
KW - Collision-type
KW - HO-CO-NaCl fluid
KW - Molybdenite solubility
KW - Molybdenum partitioning
KW - Porphyry molybdenum deposit
UR - http://www.scopus.com/inward/record.url?scp=85111630080&partnerID=8YFLogxK
U2 - 10.1016/j.chemgeo.2021.120438
DO - 10.1016/j.chemgeo.2021.120438
M3 - Article
AN - SCOPUS:85111630080
VL - 583
JO - Chemical geology
JF - Chemical geology
SN - 0009-2541
M1 - 120438
ER -