Formation and preservation of the Bayan Obo Fe-REE-Nb deposit, Inner Mongolia: Insights from evidences of petrogenesis, geochemistry and apatite fission track dating

IF 2 4区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
Pengfei Tian , Xiaoyong Yang , Wanming Yuan
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引用次数: 2

Abstract

The Bayan Obo ore deposit in Inner Mongolia, North China, the largest-known rare earth element (REE) deposit in the world, has attracted considerable attention over the past decades. However, its genesis has been highly debated, especially whether the host dolomite is of sedimentary or igneous origin. In this study, we present a comprehensive study on field geology, petrographic, geochemical, and apatite fission track analyses on REE-mineralized dolomite (H8) and its wall-rock (H9), in an effort to provide additional insights into the formation and preservation of this giant ore deposit. According to field geology and petrology analyses, the ore-hosted dolomite of the H8 unit in/around the Bayan Obo deposit displays the characteristics of sedimentary carbonates and demonstrates complicated deformation and hydrothermal events that resulted in the complex REE mineralization. The parameter of w(As) in pyrite ranging from 100 to 1600 ppm suggesting that the pyrite of the Bayan Obo deposit was mainly formed in a hydrothermal environment, and the thermal event from pyrite at ~440 Ma may represent the mineralization event of the Bayan Obo deposit, or it is an important disturbance event after the mineralization of the deposit. The geochemical research depicts that the evolution process of carbonatite was originated from calcium carbonatites and magnesio-carbonatites to ferro-carbonatite, indicating that the different genesis models of the Bayan Obo deposit that ranging from sedimentary carbonate to volcano-sedimentary and igneous carbonatites are reasonable. The two apatite ages obtained from granite on the east side of the Bayan Obo deposit and the dolomite in the Bayan Obo deposit are ~173 Ma and ~54 Ma, respectively. Time–temperature (t–T) histories of rocks yield new information about the timing of deformation of the Bayan Obo deposit, implying that the east side of the deposit experienced a rapid cooling process between ~300 Ma to ~54 Ma (especially ~300–180 Ma), this reflects the granite underwent a rapid cooling process which coeval with the plate subduction during the closure of the Palaeo-Asian Ocean, while the tectonic movement has little effect on the broken of the H8 dolomite in the mining area. Although the slate of the H9 unit from the east of the Bayan Obo deposit experienced a strong fragmentation in the later tectonic movement, it still made a great contribution to the mineralization for better preservation of REE-rich fluids, leading to the formation of the giant Fe-REE-Nb deposit.

Abstract Image

内蒙古白云鄂博Fe-REE-Nb矿床的形成与保存:来自岩石成因、地球化学和磷灰石裂变径迹测年的启示
内蒙古白云鄂博矿床是世界上已知的最大的稀土矿床,在过去的几十年里引起了人们的广泛关注。然而,其成因一直备受争议,特别是寄主白云岩是沉积成因还是火成岩成因。在这项研究中,我们对稀土矿化白云岩(H8)及其围岩(H9)进行了野外地质、岩石学、地球化学和磷灰石裂变径迹分析的综合研究,以期对这个巨大矿床的形成和保存提供更多的见解。根据野外地质和岩石学分析,白云鄂博矿床H8单元含矿白云岩具有沉积碳酸盐岩特征,并表现出复杂的变形和热液活动,形成了复杂的稀土矿化。黄铁矿w(As)参数在100 ~ 1600 ppm范围内变化,表明白云鄂博矿床黄铁矿主要形成于热液环境,~440 Ma黄铁矿热事件可能代表白云鄂博矿床成矿事件,也可能是矿床成矿后的重要扰动事件。地球化学研究表明,碳酸盐岩的演化过程是由钙碳酸盐、镁碳酸盐到铁碳酸盐,表明白云鄂博矿床由沉积碳酸盐到火山沉积碳酸盐和火成岩碳酸盐的不同成因模式是合理的。白云鄂博矿床东侧花岗岩和白云岩的磷灰石年龄分别为~173 Ma和~54 Ma。时间——温度(t t)历史的岩石产生新的信息的时机鄂博存款的变形,这意味着东矿床经历了快速冷却过程的马~ 300 Ma ~ 54岁之间(尤其是~ 300 - 180 Ma),这反映了花岗岩进行了快速冷却过程与板块俯冲在同时代的关闭Palaeo-Asian海洋,而构造运动影响不大的破碎H8矿区白云岩。巴彦鄂博矿床东部H9单元板岩虽然在后期构造运动中经历了强烈的碎裂作用,但仍为成矿作用做出了巨大贡献,使富ree流体得以更好地保存,形成了巨型Fe-REE-Nb矿床。
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来源期刊
Solid Earth Sciences
Solid Earth Sciences GEOSCIENCES, MULTIDISCIPLINARY-
CiteScore
3.60
自引率
5.00%
发文量
20
审稿时长
103 days
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