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利用带能谱仪的扫描电镜、电子探针、傅立叶红外光谱仪和激光拉曼光谱仪对日本奈良县吉野郡天川村彩虹石榴石样品进行了矿物结构、化学组成及光谱学特征的研究,分析彩虹效应成因,推测其形成环境。背散射图像可见深浅不一的条带交互排列,能谱半定量分析显示,浅灰色条带元素组成与较纯的钙铁榴石一致,深灰色条带元素组成为含Al的钙铁榴石,两者互层形成薄层结构,这种特殊结构使光发生干涉和衍射作用从而产生彩虹效应。电子探针测试确定日本彩虹石榴石主体成分接近纯钙铁榴石。在彩虹色矿物表面(简称彩虹面),垂直的薄层结构构成衍射光栅,使入射光产生光栅衍射,而平行彩虹面生长的薄层使入射光发生干涉作用,两种作用产生的光波结合形成彩虹色。日本彩虹石榴石的反射红外光谱中可见[Si O4]峰位以及受少量Al—O结构影响的Fe—O结构峰位,其红外光谱特征与含有少量Al的钙铁榴石结构对应。激光拉曼光谱测试发现Al含量高的部分较Al含量低(或无)的部分峰位向高频方向移动2 cm-1,整体谱学特征与钙铁榴石特征一致。日本彩虹石榴石具有钙铁榴石和铝含量较高的钙铁榴石交互排列的结构,据此推测其在富Fe贫Al的环境中形成。 相似文献
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I.R. Plimer 《Australian Journal of Earth Sciences》2013,60(1):147-153
An extensive complex zoned skarn is developed at the contact of a leucoadamellite intrusive at Doradilla, NW New South Wales. The skarn is a disequilibrium assemblage resulting from a progressive sequence of replacement of a carbonate precursor. Early grossular‐clinopyroxene rocks are replaced by andradite with 0.5–3.5 wt.% SnO2 clinopyroxene and quartz. Later alteration along fractures and bedding planes of the garnet‐clinopyroxene quartz assemblage has produced calcite‐malayaite (CaSn0.95Ti0.05SiO5) veins. The final replacement stage was the overprinting of the silicate phases by assemblages containing sulphides, cassiterite, magnetite, titanite, fluorite, biotite and chlorite. The tin content of garent increases with increasing andradite component suggesting replacement of Fe3+ by Sn4+. Associated clinopyroxenes contain 0.1% SnO2. The coexistence of titanite and its tin isomorph malayaite with extremely limited solid solution indicates late stage skarn temperatures of less than 400°C. 相似文献
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富钛钙铁榴石是硅不饱和碱性火成岩中的特征矿物,其Ti含量和Ti进入石榴石的方式可直接反映岩浆体系的硅饱和度和氧逸度。河北矾山超镁铁岩-正长岩杂岩体是华北克拉通北缘东西向展布三叠纪碱性岩带的重要岩体之一,其岩石中发育三种类型的富钛钙铁榴石:类型Ⅰ发育于岩体外带的石榴石辉石正长岩中,与辉石、黑云母呈岩浆共生关系,端元组成为Adr_(25-65)Mmt_(15-37)Slo_(8-28)Grs_(10-14),以高TiO_(2)含量(6.08%~18.61%)、较低的SiO_(2)含量(25.46%~33.26%)为特征,为原生岩浆成因;类型Ⅱ见于各类岩石,呈细粒他形充填于其他矿物颗粒之间,端元组成为Adr_(57-69)Mmt_(5-19)Slo_(0-6)Grs_(19-27),以高Al_(2)O_(3)含量(3.95%~5.56%)为特征,为岩浆演化后期熔体富Al_(2)O_(3)时结晶而成;类型Ⅲ亦见于各类岩石,主要呈细粒他形或细碎状发育于其他矿物内,端元组成为Adr_(68-79)Mmt_(8-14)Slo_(0-5)Grs_(6-14),以低的Al_(2)O_(3)含量(1.18%~2.89%)和较高的FeO含量(21.65%~24.62%)为特征,为岩浆期后热液成因。在矾山杂岩体的富钛钙铁榴石中,Ti主要以Si→Ti^(4+)和2Fe^(3+)→Ti^(4+)+Fe^(2+)/Mg替代方式进入到晶体结构中,反映了矾山杂岩体的母岩浆体系为二氧化硅不饱和的碱性岩浆,并具有较高的氧逸度。受石榴石的主量元素组成和相应的晶体结构控制,在微量元素组成上,矾山杂岩体中的富钛钙铁榴石富集轻稀土或中稀土、亏损重稀土,大离子亲石元素(Rb、Ba、Pb和Sr)含量较低或极低,而高场强元素(如Th、U、Nb、Ta、Zr和Hf等)含量普遍较高。本文对石榴石的成因研究结果支持矾山杂岩体不同类型的岩石形成于封闭体系下同一母岩浆系统充分的结晶-分异和堆晶作用;此演化模式可以较好地解释矾山杂岩体的同心环状特征和韵律层状结构,以及磁铁矿和磷矿的成因。 相似文献
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Abstract. Talnakhite occurs in an andradite skarn forming adjacent to a leucocratic quartz monzonite dike intruded into limestone at Fuka. The mineral densely contains exsolution lamellae of chalcopyrite, and the talnakhite-chalcopyrite inter-growth is intimately associated with bornite that contains chalcopyrite as a lattice-form exsolution. The chemical composition of the talnakhite acquired on an electron probe microanalyzer corresponds to Cu9.00 Fe8.08 S15.92 , very close to the ideal chemical formula Cu9 Fe8 S16 . Nickel is not detected. The X-ray powder diffraction lines are well indexed on a body-centered cubic cell with a = 10.589 Å. The characteristic (110) reflection of talnakhite is clearly observed at 7.49 Å. The present talnakhite retains the chalcopyrite-like colored polished surface without tarnish in air more than a month.
Talnakhite at Fuka is likely to be derived from breakdown of Cu-rich intermediate solid solution ( iss ), which was in equilibrium with Fe-rich bornite at elevated temperatures. Talnakhite thus formed has survived the subsequent cooling processes, probably because the ƒs 2 was maintained in suitable levels preventing its decomposition into bornite and chalcopyrite. 相似文献
Talnakhite at Fuka is likely to be derived from breakdown of Cu-rich intermediate solid solution ( iss ), which was in equilibrium with Fe-rich bornite at elevated temperatures. Talnakhite thus formed has survived the subsequent cooling processes, probably because the ƒ
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宝石矿物—钙铁榴石的物化性质研究及评价 总被引:2,自引:0,他引:2
应用电子探针等矿物物理分析测试技术,对我国某地发现的宝石级石榴石─钙铁榴石宝石矿物进行物化性质方面的研究,并对宝石作了初步评价。 相似文献
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Experimental observations using transmission electron microscopy (TEM) indicate that Fe3+-rich grossular–andradite solid solutions with oscillatory zoning tend to occur as separate lamellae of andradite and intermediate compositions (Hirai and Nakazawa 1986; Pollok et?al. 2001). From one lamella to the next, the Fe3+ concentration can change significantly within a few nm. In order to understand the Fe3+ and Al content of each phase and the thermodynamics, chemistry, structure, and stability at the interfaces, Monte Carlo simulations were performed. According to our calculations, there is an ordered structure with a 1:1 ratio of Al and Fe3+ with alternating Al and Fe octahedra along the main cubic crystallographic axes. Even though this ordered grandite is more energetically favorable than a 1:1 mixture of the end members grossular and andradite [by ≈1.6?kJ (mol exchangeable cations)?1], this structure is stable only at temperatures below ≈500?K. Enthalpies, free energies, configurational and vibrational entropies of mixing, and the long-range order parameter are influenced by the formation of ordered grandite below 500?K. These data also explain why interfaces are stable only between grossular and grandite or between andradite and grandite but not between the end members. The interface energies between the end members and ordered grandite are comparably low [0.16?meV?Å?2∥(1?0?0), 0.55?meV?Å?2∥(1?1?0), 0.63?meV?Å?2∥(1?1?1)] and, therefore, do not hinder the formation of lamellae. Our calculations on the free energies of mixing indicate that there are miscibility gaps between grossular and grandite and between grandite and andradite only below ≈430?K. Since most of these solid solutions are formed at higher temperatures for which we did not find evidence of a miscibility gap, the formation of compositional oscillations is probably due to kinetic hindering of thermodynamically stable complete solid solutions. ?A new methodological aspect is the incorporation of zero-point energies of vibrations and the vibrational entropies into the calculation of the free energy of mixing. In case of the grossular–andradite solid solution, these vibrational effects change the free energy of mixing by only a few percent. 相似文献
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宁镇中段铜多金属矿床与矽卡岩、尤以石榴子石矽卡岩关系密切,故从矿物学角度研究该区矽卡岩的石榴子石与成矿的关系具有现实找矿意义。通过现场观察、光学显微镜、扫描电镜、X射线衍射分析、微区能谱分析及成矿元素含量分析等,对宁镇中段矽卡岩石榴子石的形貌、结构、成分、种类及其与成矿的关系进行研究,结果表明:本区石榴子石属钙铝-钙铁榴石系列,但铜矿化区的石榴子石均属其中的钙铁榴石亚种,并且铜矿化区石榴子石的铜含量远远低于无矿化区石榴子石。研究认为,成矿元素在矽卡岩期的富集或分散趋势是石榴子石成矿元素含量高低的关键原因,若岩浆分异出来的成矿元素总量相同,则在矽卡岩期即富集到石榴子石等矿物使其成矿元素较高不利于成矿,反之则石榴子石成矿元素较低而矽卡岩期后热液具有利物质条件利于成矿。 相似文献
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