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研究生: 夏文昱
Hsia, Wen-Yu
論文名稱: 中國四川白馬火成雜岩之實驗岩石學研究與鐵-鈦-釩-氧化物礦床成因隱示
An experimental petrological investigation of the bi-modal gabbro-syenite Baima igneous complex, SW China - Implications for the genesis of Fe-Ti-V-oxide ore deposits
指導教授: 劉德慶
Liu, Teh-Ching
謝奈特
John Gregory Shellnutt
學位類別: 碩士
Master
系所名稱: 地球科學系
Department of Earth Sciences
論文出版年: 2015
畢業學年度: 103
語文別: 英文
論文頁數: 100
中文關鍵詞: 白馬火成雜岩鐵鈦釩氧化物礦床實驗岩石學
英文關鍵詞: Fe-Ti-V oxide, Baima igneous complex
論文種類: 學術論文
相關次數: 點閱:132下載:6
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    The Baima igneous complex (BIC) consists of a cumulate layered gabbroic unit, a thick Fe-Ti oxide ore zone and an isotropic peralkaline quartz syenite. The BIC contains 1150 Mt of Fe, 44.8 Mt of Ti and 2.85 Mt of V and is one of at least five world class orthomagmatic oxide deposits in the Emeishan large igneous province. The formation of the oxide deposit of the BIC is debated. There are two different models on the formation of Fe-Ti-V oxide ore in the Baima intrusion. One model suggests fractional crystallization of a basaltic parental magma led to the early crystallization of Fe-Ti oxide minerals whereas the second model suggests silicate immiscibility during the early stages of the evolution of a ferro-basaltic magma. The purpose of this study is to determine if a parental magma similar to high-Ti Emeishan basalt can produce all three rock-types observed in the BIC by experimental petrology at atmospheric pressure and mid-crustal pressure (i.e. 1 GPa).
    The experimental results at atmospheric pressure show that the liquidus temperature and solidus temperature of the basaltic melt are estimated to be 1303 oC and 1120 oC. The crystallization sequence is determined as: titanomagnetite, plagioclase (An65) and pyroxene (Wo43-47En32-45Fs11-23). The residual glass composition, represented by the quenched glass, evolves from lower SiO2 (SiO2 = ~45 wt %) values to higher SiO2 values (SiO2 = ~60 wt %) with corresponding decrease in Ti, Fe, Mg, Ca and increase of Na and K. The experimental results at 1 GPa show that the liquidus temperature is ~1220 oC, whereas the solidus temperature is estimated to be 980 oC. The crystallization sequence of the basaltic melt at 1 GPa is determined to be: titanomagnetite, pyroxene (Wo37-46En33-38Fs18-25) and plagioclase (An36).
    The most evolved glass compositions in the low and high pressure experiments are similar to the enclaves of the Baima syenitic unit but only the low pressure experiments could reproduce the mineral compositions observed in the Baima gabbroic unit. Thus, the liquidus mineral is iron-titanium oxide which is consistent with the observation of basal oxide-ore formation in the gabbroic unit. The low pressure results of this study indicate that early crystallization of Fe-Ti oxides will occur assuming a geologically reasonable starting material and that the residual liquid is silicic. The direct implication is that the oxide deposits and spatially associated granitic rocks formed together by crystallization from a basaltic parental magma. Furthermore, it is suggested that crystallization of a typical high-Ti basaltic parental magma can produce world-class giant magmatic oxide ore deposits and that the occurrence of some alkaline granites may be an indicator of their presence.

    Acknowledgement i Abstract ii Table of content iv List of tables vi List of figures vii 1 Introduction 1 1-1 Geological background 4 1-1-1 Geology of SW China (South China Block and Songpan Ganze terrane) 4 1-1-2 Layered gabbroic intrusions of the Panzhihua-Xichang region 9 1-1-3 Baima igneous complex 13 1-1-4 Mafic dykes 14 1-1-5 Origin of the Baima Fe-Ti-V oxide models 18 1-2 Purpose 19 2 Experimental methods of petrological investigation 20 2-1 Anhydrous high-temperature experiment at 0.001 GPa 22 2-2 Anhydrous high pressure high temperature experiment at 1 GPa 30 2-3 Scanning electron microscope (SEM) 34 2-4 Electron probe micro analyzer (EPMA) 35 2-5 Laser ablation- inductively coupled plasma-mass spectrometry (LA-ICPMS) 36 3 Results 38 3-1 Anhydrous high-temperature experiment at atmospheric pressure 38 3-1-1 SEM analysis 41 3-1-2 Mineral composition of the synthetic phases 46 3-1-2-1 Major elements 46 3-1-2-1-1 Fe-Ti oxide mineral 46 3-1-2-1-2 Pyroxene 48 3-1-2-1-3 Plagioclase 48 3-1-2-1-4 Glass 53 3-1-2-2 Trace elements 57 3-2 Anhydrous high pressure high temperature experiment at 1 GPa 63 3-2-1 SEM analysis 63 3-2-2 Mineral composition of the synthetic phases 68 3-2-2-1 Fe-Ti oxide 68 3-2-2-2 Pyroxene 70 3-2-2-3 Plagioclase 70 3-2-2-4 Glass 76 4 Discussion 79 4-1 Texture of minerals 79 4-2 Mineral and residual melt composition 81 4-3 Implication of oxide ore deposit genesis 89 4-4 Origin of the Baima Fe-Ti-V oxide deposit: silica immiscibility or fractional crystallization? 93 5 Conclusions 95 6 References 97

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