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11.
辽宁五龙金矿是辽东地区大型岩浆热液型矿床之一,成矿作用主要与中生代火成岩有关,为了进一步理清五龙地区中生代火成岩成因,本文对五龙金矿区大量花岗斑岩脉、闪长岩脉、三股流岩体和其中的各类脉岩进行了单颗粒锆石LA-ICPMS U-Pb测年和岩石主、微量元素地球化学研究。结果表明,五龙地区岩浆岩形成时代主要有晚侏罗世和早白垩世,矿区内近南北向展布的花岗斑岩脉形成于晚侏罗世(154.3±0.9~155.6±1.1 Ma),指示矿区在晚侏罗世受到区域最大主应力方向为近南北向;三股流岩体成岩最新年龄(116.8±0.8~117.3±0.7 Ma)基本位于前人报道的年龄范围(111~129 Ma);地球化学数据表明各类岩浆岩属于高钾钙碱性—钾玄岩系列,具有相同源区特征,形成于活动大陆边缘俯冲伸展环境下的弧岩浆,并且具有壳幔混合及进一步演化特征;结合不同深度标高成矿元素丰度特征,指示闪长岩与成矿作用密切相关,并且越往深部成矿潜力越大,对该地区找矿预测具有重要指导意义。 相似文献
12.
近年来相继在嫩江多宝山地区发现了一系列晚三叠世岩浆岩。但该期岩浆活动的构造背景、成因机制及成矿作用迄今尚未得到很好的解读,这些问题对深入理解该地区构造演化、寻找多金属矿产具有重要意义。本文以多宝山矿区英云闪长岩、争光矿区闪长岩为研究对象进行系统的岩石学、地球化学及同位素年代学研究。锆石的LA-ICP-MS定年结果表明,多宝山英云闪长岩形成时代为(226.3±2.3) Ma,争光闪长岩形成时代为(229.3±3.1) Ma,两者在误差范围内一致,可能是同一岩浆房演化的产物。地球化学特征显示,多宝山英云闪长岩以高SiO2(64.25%~66.44%)、Al2O3(16.54%~17.21%)、K2O+Na2O(8.16%~8.49%),低CaO(2.27%~2.95%)、MgO(0.99%~1.16%)、TiO2(0.31%~0.36%)、P5O2(0.16%~0.17%)为特征;争光闪长岩以SiO2(57.12%~58.5%)、Al2O3(14.59%~15.26%)、(Na2O+K2O)(5.34%~6.16%)、 TiO2(0.83%~0.97%)、P2O5(0.15%~0.27%)及TFeO/MgO(1.12~1.25)相近为特征;多宝山英云闪长岩亏损Rb、Nb、Sm,富集Ba、U、Zr和Sr,Eu正异常明显(δEu=1.21~1.57),争光闪长岩Rb、Nb、Sm亏损,Ba、Th、Sr、Hf富集,Eu弱正异常(δEu=0.93~1.22)。二者富集轻稀土元素(LREE),亏损重稀土元素(HREE),稀土及微量曲线形态近似,显示同一源区的特征,原始岩浆起源于受俯冲流体交代的地幔楔的部分熔融,形成于与蒙古—鄂霍茨克洋板块俯冲有关的活动大陆边缘环境。多宝山矿集区晚三叠世钙碱性岩浆岩的确定指示蒙古—鄂霍茨克洋俯冲作用可影响到兴安地块东缘。综合区域晚三叠世矿床成矿时代及成矿背景,证实多宝山地区晚三叠世岩浆活动具有较强的银铜钼成矿能力,成矿潜力巨大。 相似文献
13.
青海昆仑河北地区靠近昆中断裂带,经历早古生代、晚古生代—中生代多期岩浆活动,近年来自西至东陆续发现黑海北、拉陵灶火、苏海图、加祖它士西、向阳沟、加祖它士东、大灶火、黑刺沟等多个金矿床(点),形成一条东西长度近150 km长的成矿带。文章在总结带内金矿成矿基本特征基础上,选取黑海北金矿和加祖它士东金矿的赋矿围岩开展锆石U-Pb定年,结果显示黑海北硅化二长花岗岩锆石206Pb/238U加权平均年龄为443±8 Ma,形成于原特提斯洋向柴达木地块俯冲碰撞后伸展环境;加祖它士东的花岗闪长岩脉含有较多的继承锆石,锆石206Pb/238U加权平均年龄为250±1 Ma,继承锆石206Pb/238U加权平均年龄为420±2 Ma,加祖它士东花岗闪长岩侵位于古特提斯洋向北俯冲背景下的大陆弧构造环境。综合分析认为昆仑河北地区金矿成矿作用与早中生代三叠纪岩浆活动关系更为密切,其矿床类型存在造山型金矿与岩浆热液型金矿两种不同认识。昆仑河北地区土壤化探异常、低阻高极化激电异常、主要断裂(穿矿区)的次级断裂形成的蚀变破碎带等可以作为区内主要的找矿标志,推测该成矿带具有较大的找矿前景。 相似文献
14.
为查明甘肃北山前红泉一带地层、岩浆岩、构造等地质特征和成矿地质条件,总结成矿规律,进行矿产资源远景评价和成矿预测,开展了1∶5万前红泉等三幅矿产远景调查工作。通过4个年度工作,重新厘定了工作区地层系统,建立了区内岩浆岩演化序列,在构造解析的基础上探讨区域构造演化史。将"O-S"地层(敦煌岩群)解体为4个填图单元,首次发现了黑山头埃达克岩,新发现各类矿产地、矿(化)点17处。通过综合研究,圈定6处找矿远景区和10处找矿靶区;对北山地区"O-S"地层(敦煌岩群)进行了重新认识,对北山韧性剪切带金矿找矿前景及钴矿找矿方向等提出了思考和展望。 相似文献
15.
藏南冈底斯岩基东段朗县杂岩早白垩世岩浆作用:新特提斯洋二次俯冲 总被引:1,自引:1,他引:0
新特提斯洋长期俯冲消减作用在早白垩世可能经历二次俯冲启动或板片俯冲几何形态的重大转换。确定西藏南部冈底斯岩基早白垩世岩浆作用的岩石地球化学特征和作用方式是甄别上述过程的关键,对理解新特提斯洋的俯冲演化过程至关重要。本文就冈底斯岩基东段朗县杂岩中保存的各类早白垩世岩浆岩,开展了锆石U-Pb地质年代学和Hf同位素、全岩元素和同位素(Sr-Nd)组成分析。数据结果表明:1)基性岩侵位时代为早白垩世晚期(103.6~100.8Ma),为高钾钙碱性偏铝质岩石,锆石εHf(t)=+0.3~+5.7,全岩εNd(t)=-0.8和-0.3,暗示其岩浆源区具有大量俯冲沉积物或流体的混入,为沉积物熔体和流体交代的地幔楔物质部分熔融的产物,经历了一定程度的角闪石分离结晶作用;2)中性岩形成于99.8~97.6Ma,略晚于基性岩,其主量元素与基性岩具有较好的线性关系,全岩εNd(t)=+1.1,具有较多的地幔物质参与,为基性岩浆进一步演化形成;3)酸性岩(脉体)记录了多阶段岩浆作用(124.1~95.3Ma),根据同位素组成不同进一步划分为两类,第一类具有较低的全岩εNd(t)值(-8.3~-6.0),其岩浆源区显示富集特征,tDM2=1385~1586Ma,由古老地壳物质的再熔融形成;第二类的锆石εHf(t)值(-2.8~+3.2)变化较大,岩脉的锆石εHf(t)=+0.4~+8.1,tDM=428~906Ma,全岩εNd(t)=+0.1和+0.8,表明岩浆源区具有不均一性,为古老地壳物质被富流体地幔岩浆改造形成;和4)镁铁质包体的主量元素与寄主花岗岩具有较好的线性关系,锆石的Hf同位素组成变化较大(εHf(t)=-9.3~+4.1),变化范围可达13个ε单位,为岩浆混合成因。寄主花岗岩和角闪辉长岩分别作为酸性和基性端元,是基性岩浆与其诱发古老地壳熔融形成的花岗质岩浆经混合形成。结合冈底斯岩基早白垩世岩浆岩的研究结果,朗县杂岩在早白垩世(124~97Ma)的岩浆作用具有明显的岩浆混合现象,锆石Hf和全岩Sr-Nd同位素组成变化较大,可达13个ε单位,其岩浆源区复杂且富含流体,代表了新特提斯洋在早期(240~144Ma)经历漫长的俯冲之后,在早白垩世时期(~120Ma)俯冲带发生跃迁或俯冲角度达到临界点,导致大量俯冲沉积物和流体沿俯冲带俯冲下去,与发生部分熔融的地幔楔物质混合,底侵导致上覆古老地壳物质的再熔融,形成早白垩世复杂的岩浆岩组合,很可能是新特提斯洋二次俯冲开始的标志。 相似文献
16.
南海大洋钻探及海洋地质与地球物理前沿研究新突破 总被引:2,自引:2,他引:0
南海是西太平洋地区规模最大且具有代表性的边缘海盆地之一。经过近几十年的研究积累,尤其是通过实施5个国际大洋钻探航次(1999–2018年)与国家自然科学基金委“南海深海过程演变”重大研究计划(2011–2019年),我国科学家获得了大量宝贵的第一手资料,取得了一系列创新进展与重大突破,标志着南海海洋地质与地球物理研究正走向国际前沿。重要研究成果包括:(1)新提出南海是“板缘张裂”盆地,与经典的大西洋型陆缘模式不同;(2)大洋钻探首次获取了基底玄武岩样品,结合中国在南海首次深拖地磁测量实验,精确测定了南海海盆玄武岩年龄,揭示南海海盆从东向西分段扩张;(3)大洋钻探结果发现南海陆缘岩石圈减薄之初岩浆迅速出现,未发现缓慢破裂造成的蛇纹岩出露;(4)发现南海扩张结束后仍存在大量岩浆活动,可能受控于多种构造与地幔因素;(5)地球化学证据与地球动力学模拟都显示南海岩浆的形成受到周边俯冲带的影响。目前我国的海洋地球科学正在进入崭新的发展阶段,有望以南海为基点,开始拓展到周边大洋,通过主导大型研究计划以及建设我国大洋钻探平台,以提升我国在南海、西太平洋与印度洋海洋地质科学研究的实质性影响力与引领地位。 相似文献
17.
Natural evaporite dissolution in the subsurface can lead to cavities having critical dimensions in the sense of mechanical stability. Geomechanical effects may be significant for people and infrastructures because the underground dissolution may lead to subsidence or collapse (sinkholes). The knowledge of the cavity evolution in space and time is thus crucial in many cases. In this paper, we describe the use of a local nonequilibrium diffuse interface model for solving dissolution problems involving multimoving interfaces within three phases, that is, solid–liquid–gas as found in superficial aquifers and karsts. This paper generalizes developments achieved in the fluid–solid case, that is, the saturated case [1]. On one hand, a local nonequilibrium dissolution porous medium theory allows to describe the solid–liquid interface as a diffuse layer characterized by the evolution of a phase indicator (e.g., porosity). On the other hand, the liquid–gas interface evolution is computed using a classical porous medium two‐phase flow model involving a phase saturation, that is, generalized Darcy's laws. Such a diffuse interface model formulation is suitable for the implementation of a finite element or finite volume numerical model on a fixed grid without an explicit treatment of the interface movement. A numerical model has been implemented using a finite volume formulation with adaptive meshing (e.g., adaptive mesh refinement), which improves significantly the computational efficiency and accuracy because fine gridding may be attached to the dissolution front. Finally, some examples of three‐phase dissolution problems including density effects are also provided to illustrate the interest of the proposed theoretical and numerical framework. Copyright © 2014 John Wiley & Sons, Ltd. 相似文献
18.
Petrochemical studies of granitoid rocks from the eastern part of Kumaun region suggest that the leading edge of India represents an active arc during Late Paleoproterozoic times. It has been observed that melt generation for granodiorite rocks from the eastern Almora Nappe and Chhiplakot klippe along with the Askot klippe was caused through a subduction‐related process involving hydrous partial melting of a Paleoproterozoic amphibole‐ and/or garnet‐bearing mafic source with the involvement of sediments from the subduction zone. The medium‐ to high‐K basic rocks, common in subduction‐related magmatic arcs, can also explain the generation of the high‐K granodiorites of the Chhiplakot klippe. The augen gneisses from the eastern Almora nappe and Chhiplakot klippe along with the Askot klippe further show geochemical similarity with the associated granodiorites, suggesting there is a genetic linkage with one another. 相似文献
19.
Zhou Taofa Wu Mingan Fan Yu Duan Chao Yuan Feng Zhang Lejun Liu Jun Qian Bing Franco Pirajno David R. Cooke 《Ore Geology Reviews》2011,43(1):154-169
The Middle-Lower Yangtze (Changjiang) River Valley metallogenic belt is located on the northern margin of the Yangtze Craton of eastern China. Most polymetallic deposits in the Changjiang metallogenic belt are clustered in seven districts where magmatism of Mesozoic age (Yanshanian tectono-thermal event) is particularly extensive. From west to east these districts are: E-dong, Jiu-Rui, Anqing-Guichi, Lu-Zong, Tong-Ling, Ning-Wu and Ning-Zhen. World-class iron ore deposits occur in the Lu-Zong and Ning-Wu ore clusters, which are mainly located in continental fault-bound volcanic-sedimentary basins. One of these deposits is the Longqiao iron deposit, discovered in the northern part of the Lu-Zong Basin in 1985. This deposit consists of a single stratabound and stratiform orebody, hosted in sedimentary carbonate rocks of the Triassic Dongma'anshan Formation. A syenite pluton (Longqiao intrusion) is situated below the deposit. The iron ore is massive and disseminated and the ore minerals are mainly magnetite and minor pyrite. Wall rock alteration mostly consists of skarn minerals, such as diopside, garnet, potassic feldspar, quartz, chlorite, phlogopite and anhydrite. Thin sedimentary siderite beds of Triassic age occur as relict laminated ore at the top and the margin of the magnetite orebody. These sideritic laminae are part of Triassic evaporite-bearing carbonate deposits (Dongma'anshan Formation).Sulfur isotopic compositions show that the sulfur in the deposit was derived from a mixture of magmatic hydrothermal fluids and carbonate–evaporite host rocks. Similarly, the C and O isotopic compositions of limestones from the Dongma'anshan Formation indicate that these rocks interacted with magmatic hydrothermal fluids. The O isotopic compositions of the syenitic rocks and minerals from the deposit show that the hydrothermal magnetite and skarn minerals were formed from magmatic fluids. The Pb isotopic compositions of sulfides are similar to those of the Longqiao syenite. Phlogopite coexisting with magnetite in the magnetite ores yielded a plateau age of 130.5 ± 1.1 Ma (2σ), whereas the LA-ICP MS age of the syenite intrusion is 131.1 ± 1.5 Ma, which is slightly older than the age of phlogopite.The Longqiao syenite intrusion may have crystallized from a parental alkaline magma, generated by partial melting of lithospheric mantle, during extensional tectonics. The ore fluids were probably first derived from magma at depth, later emplaced in the sedimentary rocks of the Dongma'anshan Formation, where it interacted with siderite and evaporite-bearing carbonate strata, resulting in the formation of magnetite and skarn minerals. The Longqiao iron deposit is a skarn-type stratabound and stratiform mineral system, genetically and temporally related to the Longqiao syenite intrusion. The Longqiao syenite is part of the widespread Mesozoic intracontinental magmatism (Yanshanian event) in eastern China, which has been linked to lithospheric delamination and asthenospheric upwelling. 相似文献
20.