Rb-Sr ISOCHRON AGE OF FLUID INCLUSIONS IN THE QUARTZ OF XUJIACUN GOLD DEPOSIT, HEILONGJIANG PROVINCE
TIAN Bing-qiang1, WANG Sheng-peng2, QI Zhong-you1
1. Heilongjiang Institute of Regional Geological Survey, Harbin 150080, China; 2. School of Earth Sciences, Chengdu University of Technology, Chengdu 610059, China
Abstract:The Xujiacun gold deposit is located in the southwest of Jiamusi block, with the orebody occurred in the Late Permian monzogranite. The metallogenic age is obtained and the ore-forming fluid source and its genetic relation with the host granite are discussed through the determination of Rb-Sr isotope age and H and O isotopes of fluid inclusions in the quartz of gold veins. The results show that the Rb-Sr isochron age is 229±8.6 Ma, slightly later or close to the formation time of ore-bearing rock mass (254.2±0.95 Ma, 230.44±0.54 Ma). The H and O isotopic characteristics of quartz indicate that the ore-forming fluid was the hydrothermal solution differentiated from the Late Permian granitic magma, with a small amount of atmospheric precipitation added later, suggesting that there is a close genetic relation between the ore-bearing quartz vein and the host granite. From the above, it is believed that the diagenesis and mineralization may occur in the same geological event, both related to the subduction of Paleo-Asian Ocean Plate into the Jiamusi-Mongolia block.
田丙强, 王升鹏, 齐忠友. 黑龙江省徐家村金矿床石英流体包裹体Rb-Sr等时线年龄[J]. 地质与资源, 2020, 29(2): 113-119,141.
TIAN Bing-qiang, WANG Sheng-peng, QI Zhong-you. Rb-Sr ISOCHRON AGE OF FLUID INCLUSIONS IN THE QUARTZ OF XUJIACUN GOLD DEPOSIT, HEILONGJIANG PROVINCE. GEOLOGY AND RESOURCES, 2020, 29(2): 113-119,141.
Shepherd T J, Darbyshire D P F. Fluid inclusion Rb-Sr isochrons for dating mineral deposits[J]. Nature, 1981,290(5807):578-579.
[5]
Changkakoti A, Gray J, Krstic D, et al. Determination of radiogenic isotopes (RbSr, SmNd and PbPb) in fluid inclusion waters:An example from the Bluebell Pb-Zn deposit, British Columbia, Canada[J]. Geochimica et Cosmochimica Acta, 1988,52(5):961-967.
Norman D I, Landis G P. Source of mineralizing components in hydrothermal ore fluids as evidenced by 87Sr/86Sr and stable isotope data from the Pasto Bueno deposit, Peru[J]. Economic Geology, 1983,78(3):451-465.
[13]
Rossman G R, Weis D, Wasserburg G J. Rb, Sr, Nd and Sm concentrations in quartz[J]. Geochimica et Cosmochimica Acta, 1987, 51(9):2325-2329.
Clayton R N, Rex R W, Syers J K, et al. Oxygen isotope abundance in quartz from Pacific pelagic sediments[J]. Journal of Geophysical Research, 1972,77(21):3907-3915.
[18]
Taylor H P. The application of oxygen and hydrogen isotope studies to problems of hydrothermal alteration and ore deposition[J]. Economic Geology, 1974,69(6):843-883.
DavisG A, Xu B, Zhang Y D, et al. Indosinian extension in the Solonkersuture zone:the SonidZuoqi metamorphiccore complex, Inner Mongolia, China[J]. Earth Science Frontiers, 2004,11(3):135-144.
Miao L C, Fan W M, Liu D Y, et al. Geochronology and geochemistry of the Hegenshanophiolitic complex:Implications for late-stage tectonic evolution of the Inner Mongolia-Daxinganling Orogenic Belt, China[J]. Journal of Asian Earth Sciences, 2008,32(5/6):348-370.
Canbaz O, Gokce A. Microthermometric and stable isotopic(O and H) characteristics of fluid inclusions in the porphyry related Çöpler (İliç-Erzincan) gold deposit, central eastern Turkey[J]. Central European Journal of Geosciences, 2014,6(2):139-147.
[36]
Hedenquist J W, Lowenstern J B. The role of magmas in the formation of hydrothermal ore deposits[J]. Nature, 1994,370(6490):519-527.
[37]
Ohmoto H. Stable isotope geochemistry of ore deposits[J]. Reviews in Mineralogy and Geochemistry, 1986,16(1):491-559.
[38]
Rye R O. The evolution of magmatic fluids in the epithermal environment:the stable isotope perspective[J]. Economic Geology, 1993,88(3):733-752.
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