埃及中东部沙漠el-missikat萤石矿化的矿物学和地球化学特征:微量元素和流体包裹体约束

B. R. Bakhit
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引用次数: 0

摘要

在埃及东部沙漠中部的ElMissikat地区,不同颜色的萤石以浸染状和细脉状的形式出现在寄主花岗岩中。本文论述了该花岗质寄主岩的矿物学和地球化学特征,包括矿物化学、全岩地球化学分析。对萤石中单个流体包裹体进行了痕量、REY (REE+Y)元素、流体包裹体和LA-ICP-MS分析。岩石学上,寄主花岗岩以黑云母花岗岩为代表。给出了原生相的矿物化学数据。斜长石为钠长石(平均2.79 mol%)。黑云母为原生岩浆成因,在500 ~ 600℃结晶。地球化学特征表明,El-Missikat花岗岩为过铝质花岗岩,形成于碰撞后(板块内)环境。V型(紫色)、G型(绿色)和W型(白色)萤石样品的平均ΣREE含量分别为75.5、200.9和203.2 ppm(即从紫色萤石逐渐增加到绿色和白色萤石)。ΣREE的这些差异可能与pH条件和流体的总体化学成分的变化有关。萤石类型的Tb/Ca、Tb/La和Y/Ho比值表明它们是岩浆流体与花岗质围岩相互作用形成的。萤石表现出强烈的Eu负异常和Y正异常,与寄主花岗岩的REY异常相似,表明热液流体中稀土元素和微量元素的来源是流体浸出的寄主花岗岩。目前的研究表明,稀土元素的含量和总稀土元素的含量是造成绿色和白色外观的原因。紫色萤石中锶含量高,可能是紫色的原因。A型萤石流体包裹体(FI)均质温度为201C ~ 296C(高盐度FI), B型萤石流体包裹体(FI)均质温度为160C ~ 165C(低盐度FI)。萤石中冰的熔化温度表明其盐度可达19.4等wt% Na CI (A型),但B型FI的盐度范围较低(0.53 ~ 4.49等wt% Na Cl)。A型流体密度为0.9 ~ 1.0 g/cm, B型流体密度为0.9 g/cm。从El-Missikat萤石单个FI的LA-ICP-MS数据可以清楚地看出,A型FI比B型FI含有非常高浓度的元素。分析元素的丰度为:Ca > Na > S > K > Sr > Y > Fe, Pb > Cu > U > Cs, W, Te, Ag, As > Th > Au。萤石的沉积机制可能是流体混合、压力和温度变化以及流体-岩石相互作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
MINERALOGICAL AND GEOCHEMICAL CHARACTERISTICS OF EL-MISSIKAT FLUORITE MINERALIZATION, CENTRAL EASTERN DESERT, EGYPT: TRACE ELEMENTS AND FLUID INCLUSIONS CONSTRAINTS
Fluorite of different colours occurs as disseminations and veinlets in the host granitic rocks in ElMissikat area, central Eastern Desert, Egypt. This paper addresses the mineralogical and geochemical characteristics, including mineral chemistry, whole rock geochemical analyses of the granitic host rock. Trace, REY (REE+Y) elements, fluid inclusions and LA-ICP-MS analyses for individual fluid inclusions in fluorite were also carried out. Petrographically, the host granite represented by biotite granite. Mineral chemistry data of primary phases are given. Plagioclase is albite (average 2.79 mol%). Biotite is of primary magmatic origin and crystallized at 500 600C. Geochemically, El-Missikat granite is peraluminous Atype and was generated in post-collision environment (within plate). The average ΣREE content of Type V (violet), G (green) and Type W (white) fluorite samples are 75.5, 200.9 and 203.2 ppm, respectively (i.e. increasing from violet fluorite to green and white fluorites. These differences in ΣREE were possibly related to changes in pH condition and bulk chemical composition of the fluids. Tb/Ca, Tb/La and Y/Ho ratios of the fluorite types indicate that they were formed from the interaction between magmatic fluids and granitic wall-rocks. The fluorites show strongly negative Eu and positive Y anomalies similar to REY pattern of the host granites, indicating that the source of REE and trace elements of hydrothermal fluids is the host granite leached by fluids. The present work revealed that the contents of Y and total REE contents are responsible for the appearance of green and white colours. The Sr content is high in violet fluorite and may be responsible for violet colour. The fluid inclusions (FI) of the fluorite have homogenisation temperatures ranging from 201C to 296C in Type A (high salinity FI) and 160C to 165C in Type B (low salinity FI). The melting temperature of ice in fluorite indicates salinities up to 19.4 equiv. wt% Na CI (Type A) but Type B FI have a low range of salinity (0.53 to 4.49 equiv. wt% Na Cl). The density of fluids is 0.9 to 1.0 g/cm in Type A and 0.9 g/cm in Type B. From the LA-ICP-MS data for the individual FI of El-Missikat fluorite, it is clear that the Type A FI contains very high concentrations of elements than that in Type B FI. The abundance of the analyzed elements in the present FI is: Ca > Na > S > K > Sr > Y > Fe, Pb > Cu > U > Cs, W, Te, Ag, As > Th > Au. The deposition mechanisms for fluorite may be fluid mixing, changes in pressure and temperature and fluid-rock interaction.
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