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The evolution of ore-forming fluid and its constraint on mineralization process in Mianhuakeng uranium deposit,northern Guangdong,China

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ã€Authorã€‘ QI JiaMing;ZHU Ba;WU JianYong;CAO HaoJie;LIU WenQuan;XU ZhengQi;Research Institute No.290,China National Nuclear Corporation;College of Earth Sciences,Chengdu University of Technology;

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ã€Abstractã€‘ In this paper,the evolution of ore-forming fluid and its constraint on ore-mineralization process in the Mianhuakengï¼ˆ No. 302ï¼‰ uranium deposit has been studied by means of thermodynamics and composition of fluid inclusions in various syn-ore gangue mineralsï¼ˆ such as purple black fluorite,light pink calcite and red microcrystalline quartzï¼‰ and the trace elements of symbiosis pyrite.The results show that the inclusions of syn-ore fluorite,calcite and microcrystalline quartz were mainly liquid-rich two-phase Na Cl-H₂O with the average homogeneous temperatures of 185. 8â„ƒ,177. 0â„ƒ and 140. 4â„ƒ and average salinity of 2. 24% Na Cleqv,1. 36%Na Cleqv,1. 75% Na Cleqv respectively. That was to say,the No. 302 deposit had the characteristics of hydrothermal mineralization at low temperature and low salinity. In addition,the average ore-forming pressure was 39. 5 MPa,38. 0 MPa and 30. 1 MPa,and the average ore-forming depth was 1. 5 km,1. 3 km and 1. 1 km respectively. The composition of fluid inclusion groups has been showed that the ore-forming fluids were rich in K⁺,Na⁺,Ca^{2 +}cations,and HCO₃^-,F^-,SO₄^2- anions as well as gaseous components such as CO₂ and H₂O. It was considered that these gangues were the products of precipitation in different stages of the syn-ore period,there were evolutionary differentiation and immiscibility in the hydrothermal syn-ore process with the decreasing of temperature and pressure of the ore-forming fluid and increasing of âˆ‘M+/âˆ‘M-in the inclusions. Mineral precipitation was accompanied by the sequence of gangue mineral formation of fluorite,calcite and microcrystalline quartz. The change of Y/Ho average ration of pyrite associated with syn-ore period showed that the properties of the ore-forming fluid has been changed during the mineral precipitation process,which made the average ratio of REE and HFSE such as Zr/Hf,Nb/La,Co/Ni gradually decrease,and made the reductive syn-ore environment undergo slight microwave movement,uranium element would be precipitated with microcrystalline quartz in large quantities at the latest stage of fluid evolution,the U/Th average ratio of the precipitated pyrite was increased gradually.æ›´å¤š è¿˜åŽŸ

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ã€Key wordsã€‘ Fluid inclusionsï¼› Groups compositionï¼› Pyriteï¼› Trace elementsï¼› Evolution of ore-forming fluidsï¼› Mianhuakeng uranium depositï¼› Northern Guangdongï¼›

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The evolution of ore-forming fluid and its constraint on mineralization process in Mianhuakeng uranium deposit,northern Guangdong,China

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