Albian–Cenomanian A-type granite-related Ag–Pb–Zn veins in the central Yidun Terrane, SW China: constraints from the Xiasai deposit

Albian–Cenomanian A-type granite-related Ag–Pb–Zn veins in the central Yidun Terrane, SW China: constraints from the Xiasai deposit

The Xiasai–Lianlong metallogenic belt in the central Yidun Terrane (China) hosts several Sn–Ag and (Sn–) Ag–Pb–Zn deposits, which are spatially associated with Cretaceous granites. The Xiasai Ag–Pb–Zn deposit (about 0.27 Mt Pb+Zn, 1028 t Ag, and 20,000 t Sn) is the largest deposit in the belt and is...

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Bibliographic Details
Published in:Mineralium deposita Vol. 55; no. 6; pp. 1047 - 1070
Main Authors: Li, Yan-Jun, Wei, Jun-Hao, Tan, Jun, Fu, Le-Bing, Li, Huan, Ke, Kun-Jia
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-08-2020
Springer Nature B.V
Subjects:
Ablation
Anomalies
Barium
Composition
Computational fluid dynamics
Copper
Cretaceous
Earth and Environmental Science
Earth Sciences
Feldspars
Fluids
Fractionation
Galena
Geochronology
Geology
Granite
High temperature
Inductively coupled plasma mass spectrometry
Intrusion
Isotope fractionation
Isotopes
Laser ablation
Lasers
Lead
Low temperature
Magma
Mantle
Mass spectrometry
Mass spectroscopy
Meteoric water
Mineral Resources
Mineralization
Mineralogy
Organic matter
Rubidium
Silica
Silicon dioxide
Silver
Sodium chloride
Sphalerite
Strontium
Sulfides
Sulfur
Sulphur
Tectonics
Tin
Titanium dioxide
Veins (geology)
Zinc
Zincblende
Zircon
China
Hydrothermal Ag–Pb–Zn veins
Yidun Terrane
A-type granite
Albian–Cenomanian
Isotope geochemistry
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Summary:The Xiasai–Lianlong metallogenic belt in the central Yidun Terrane (China) hosts several Sn–Ag and (Sn–) Ag–Pb–Zn deposits, which are spatially associated with Cretaceous granites. The Xiasai Ag–Pb–Zn deposit (about 0.27 Mt Pb+Zn, 1028 t Ag, and 20,000 t Sn) is the largest deposit in the belt and is related to a monzogranite intrusion. The deposit consists of sulfides in hydrothermal veins, resulting from three successive mineralization stages (I–III). A Rb–Sr isochron of sphalerite samples yielded an age of 99 ± 3 Ma, and zircon U–Pb laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) dating of the Xiasai monzogranite gave ages between 102 ± 1 and 101 ± 1 Ma. The Xiasai monzogranite has a weakly peraluminous A-type granite composition, with high SiO 2 , alkali, and FeO t contents and low CaO, MgO, and TiO 2 contents. It is marked by enrichments in Rb, Th, and U, with depletions in Ba, Nb, Sr, P, and Ti relative to the primitive mantle. The REE patterns show a negative slope due to LREE enrichment with negative Eu anomalies (Eu/Eu* = 0.1–0.3). The Xiasai monzogranite, with variable ε Hf ( t ) values (− 2.7 to 0.6) and Meso- to Neoproterozoic two-stages Hf model ages ( T DM2  = 925–1095 Ma), was probably derived from mixing of melts derived from partial melting of the Paleoproterozoic crustal basement and the Early Cretaceous mantle in an extensional tectonic setting. Hydrothermal fluids are characterized by high temperatures (423–481 °C) and salinities (14.9–19.0 wt% NaCl) for Sn mineralization (stage I), moderate temperatures (285–386 °C) and salinities (3.5–8.0 wt% NaCl) for the Cu–Zn mineralization (substage II-2), and low temperatures (158–242 °C) and salinities (3.4–5.7 wt% NaCl) for the Ag–Pb mineralization (substage II-3). The H–O isotopes indicate that the hydrothermal fluid likely has a magmatic component that mixed over time with infiltrating meteoric water and organic matter during fluid–rock interactions. The δ 34 S values of sphalerite range from − 9.7 to − 3.1‰ and those from galena from − 10.5 to − 4.9‰. The estimated δ 34 S value of the hydrothermal fluid is − 8.5‰, using the sulfur isotopic fractionation of sphalerite–galena pairs that are interpreted to be in equilibrium. Sulfides from substages II-2 and II-3 have relatively homogeneous Pb isotopic compositions, which are similar with those of K-feldspars from the Xiasai monzogranite. Geochronological and isotope data support a magmatic–hydrothermal origin for the Xiasai Ag–Pb–Zn deposit.
ISSN:0026-4598
1432-1866
DOI:10.1007/s00126-019-00920-5