凤凰山花岗岩体构造系统分析及侵位机制

本文从宏观上对凤凰山岩体的区域构造位置、岩体侵位前后的构造演化过程及岩浆侵位时的动力学条件进行了论述;对岩体内部及接触带的面理、线理进行了磁组构测量、显微构造观察、包体应变测量及X光组构分析等系统研究,最终获得如下结论:该岩体侵位除有膨胀作用外,在岩体侵位后期还有过旋转运动,而且岩体侵位受到NNE向左旋剪切作用控制。      

湘东板杉铺岩体构造样式与侵位机制

根据板杉铺岩体的基本特征 (形态、产状、主体单元的空间分布、接触关系 )、围岩构造 (褶皱、断层、片理等 )、内部构造 (片麻理、包体、断层、节理、岩脉、岩石磁性组构 )等构造样式认为 ,板杉铺岩体侵位经历了重熔岩浆的产生→底辟上升→多次脉动式上侵的逆旋—气球膨胀的过程 ,为花岗岩体构造样式研究与就位机制分析开拓了新的思路。     

铜陵凤凰山岩体侵位构造变形特征

通过对凤凰山岩体的野外研究,显微构造,包体测量及磁组构分析,详尽解析凤凰山岩体的侵位构造变形特征,并厘定了岩体变形过程中的应变状。结果表明表明凤凰山岩体ＮＮＥ向水平左旋剪切应力及重力的联合用用下呈气囊膨胀式同构造侵位的机制。     

湘东板杉铺岩体构造样式与侵位机制

根据板杉铺岩体的基本特征（形态、产状、主体单元的空间分布、接触关系）、围岩构造（褶皱、断层、片理等）、内部构造（片麻理、包体、断层、节理、岩脉、岩石磁性组构）等构造样式认为,板杉铺岩体侵位经历了重熔岩浆的产生→底辟上升→多次脉动式上侵的逆旋－气球膨胀的过程,为花岗岩体构造样式研究与就位机制分析开拓了新的思路。     

医巫闾山岩体同伸展侵位的证据及其地质意义

医巫闾山岩体是医巫闾变质核杂岩的重要组成部分。根据医巫闾山地区花岗岩变形特征及与周围构造带的相互关系,确定医巫闾山岩体为同伸展侵位的岩体,且以岩床的形式顺层侵入在医巫闾山伸展型韧性剪切带之中,修正了前人挤压环境下岩浆侵位的观点。医巫闾山岩体及尖砬子山岩体的侵位时间在160 Ma左右,表明医巫闾山地区及燕山地区中侏罗世晚期发生过强烈的地壳伸展运动,华北北部的构造体制在中侏罗世已经改变。区内中生代存在2期伸展作用：早期伸展作用发生在中侏罗世晚期,与医巫闾山岩体的侵位同期;晚期伸展作用发生在早白垩世,形成了瓦子峪拆离断层。     

广西海洋山花岗岩体侵位构造特征

花岗岩是大陆地壳的重要组成部分,是地球动力学演化的示踪剂。花岗岩体侵位构造的研究对于揭示花岗岩体的变形历史和侵位机制具有重要的科学价值。本文研究了海洋山花岗岩体的内部构造、与岩浆侵位应力有的围岩构造及热接触变质带特征,探讨了岩体和围岩的应变状态。研究发现,从岩浆侵位到冷凝固结,海洋山花岗岩体经历了液态流动、塑性变形和“半固态”冷凝阶段的演化。岩体各单元的应变类型分别是单轴压扁、平面应变、单轴压缩,     

宁镇中段矿化斑岩体的侵位深度及剥蚀程度研究

判别岩体侵位深度对找矿富有指导意义,查明岩体剥蚀程度是评价斑岩铜矿找矿前景的重要因素之一。运用岩体"盖层"厚度恢复法、成岩温度与压力计算法、蚀变矿化分带判别法、岩体的顶垂体、捕虏体、析离体及岩脉发育状况判别法,以及岩石的结构、构造和矿物结构形态判别法,综合研究了宁镇中段主要斑岩体的侵位深度和剥蚀程度,结果表明宁镇中段侵入体总体上具有由西向东、由南向北剥蚀程度逐渐加深的特点。     

崔召花岗岩岩体的磁组构特征及其构造侵位意义

侵入岩体的磁组构形成于岩浆运移侵位、固化的过程中,必然保留了岩体的构造侵位过程的信息.以玲珑复式花岗岩岩基南部的崔召岩体为例,对岩体磁组构的详细研究,可以揭示岩浆运移,就位和变形等一系列特征.崔召岩体的磁线理不发育,反映岩体侵位速度慢,岩体边部磁面理比内部发育,并且岩体边缘磁各向异性度P值明显大于岩体内部,磁线理倾角小,反映岩体侵位过程中侧向挤压作用比较强烈,具有类似于气球膨胀作用的侵位机制.并且此磁组构特征再没有受到后期构造热事件的影响.     

安徽凤凰山岩体岩浆侵位过程的磁性研究

通过对安徽省铜陵地区凤凰山岩体25个采样点302件岩石样品的磁性分析,认为研究区内所得的岩石磁组构能代表岩浆侵位时的流动型磁组构,它受岩浆形成之后的构造活动的影响较小;岩浆侵位过程是准静态过程,岩浆流动性较弱、分异作用和同化混染作用强烈;岩浆侵位过程的早期可能受北北东方向的最大主压应力的控制,后期受西南方向最大主压应力场的控制;凤凰山岩体的西南部(药园山矿床所在地段)是岩体的上盘,北东部(仙人冲矿床所在地)是岩体的下盘,即凤凰山岩体向西南方向倾伏;凤凰山岩体的西南部附近地区(如来龙山等地),可能有与凤凰山岩体侵位同时期形成的小岩株,是找矿的远景区段。     

再考查深成岩体侵位作用

以前有关深成岩体的侵位研究都试图解释岩体侵位空间如何形成。事实上，幔源岩浆侵位期间在地壳中“制造空间”的途径不外乎；（１）莫霍面降低；（２）地球表面外移。其它的“岩体侵位机制”均是不增加地壳体积的物质迁移作用（ＭＴＰｓ）。得到广泛引用的“同心带状气球膨胀岩体”侵位时的ＭＴＰｓ是岩体附近围岩的韧性流动。这类深成岩体附近可能形成的构造和总应变与岩体的三维形态、接触变质带的宽度以及岩体是否为刺穿底辟有关     

湘南姑婆山岩体北西侧侵入接触带构造控矿研究

位于湖南南部的姑婆山岩体北西侧侵入接触带受断裂构造控制明显,表现复杂多样,是该区钨、锡多金属矿床的主要控矿构造.根据接触带不同成矿区段的空间展布特点、构造变形和矿化蚀变特征,认为该区接触带构造是岩体侵位和区域应力双重作用的结果,并首次将该侵入接触带构造划分为3种类型,即侵入接触-断裂复合型、双侵入接触-断裂复合型以及捕虏体接触-断裂复合型.明确提出了侵入接触带构造控矿的观点,从而为进一步研究其成矿及控矿作用提供必要的理论依据.     

桂东北姑婆山岩体矿物学和年代学特征及其成岩成矿意义

为揭示桂东北姑婆山一带花岗岩的成岩成矿特征,本文对姑婆山岩体进行了黑云母矿物化学成分分析和锆石U-Pb年代学研究。花岗岩中黑云母化学成分分析结果表明：黑云母具有富铁镁、贫钙钠的特征,w（TFeO）为26.78%~31.06%、w（MgO）为2.98%~6.60%,且w（TFeO）与w（MgO）呈明显的负相关性,说明其结晶过程中主要发生了Fe²⁺←→Mg²⁺的置换反应;黑云母的含铁指数为0.68~0.84,属于高铁黑云母,氧逸度为-17.0~-15.5,结晶温度为680~705℃,平均为695℃;黑云母的全铝压力计显示黑云母结晶的压力为69~179 MPa,平均为115 MPa,对应的侵位深度相当于2 621~6 755 m,平均深度为4 331 m。年代学分析结果显示,采自姑婆山岩体的两个代表性花岗岩样品形成年龄分别为（162±3）和（163±2）Ma,为燕山早期,与华南中生代大规模岩浆-成矿作用时代一致。综合上述分析,姑婆山岩体形成于较高温度、低氧逸度、较浅的环境,显示出良好的锡成矿性,具有良好的找矿前景。     

Magmatic‐Hydrothermal Mineralization Sequence in Xinlu Ore Field,Guangxi, South China: Constraints from Zircon U‐Pb,Molybdenite Re‐Os,and Muscovite Ar‐Ar Dating

The Xinlu Sn‐polymetallic ore field is located in the western Nanling Polymetallic Belt in northeastern Guangxi, South China, where a number of typical skarn‐, hydrothermal vein‐type tin deposits have developed. There are two types of Sn deposits: skarn‐type and sulfide‐quartz vein‐type. The tin mineralizations mainly occur on the south side of the Guposhan granitic complex pluton and within its outer contact zone. To constrain the Sn mineralization age and further understand its genetic links to the Guposhan granitic complex, a series of geochronological works has been conducted at the Liuheao deposit of the ore field using high‐precision zircon SHRIMP U‐Pb, molybdenite Re‐Os, and muscovite Ar‐Ar dating methods. The results show that the biotite‐monzogranite, which is part of the Xinlu intrusive unit of the Guposhan complex pluton, has a SHRIMP U‐Pb zircon age of 161.0 ± 1.5 Ma. The skarn‐type ore has a ⁴⁰Ar‐³⁹Ar muscovite plateau age of 160 ± 2 Ma (same as its isochron age), and the sulfide‐quartz vein‐type ore yields an Re‐Os molybdenite isochron age of 154.4 ± 3.5 Ma. The magmatic‐hydrothermal geochronological sequence demonstrated that the hydrothermal mineralization took place immediately following the emplacement of the monzogranite, with the skarn metasomatic mineralization stage predating the sulfide mineralization stage. Geochronologically, we have compared this ore field with 26 typical Sn deposits distributed along the Nanling Polymetallic Belt, leading to the suggestion of the magmatic‐metallogenic processes in the Xinlu ore field (ca. 161–154 Ma) as a component of the Early Yanshanian large‐scale Sn‐polymetallic mineralization event (peaked at 160–150 Ma) in the Nanling Range of South China. Petrogenesis of Sn‐producing granite and Sn‐polymetallic mineralization were probably caused by crust–mantle interaction as a result of significant lithospheric extension and thinning in South China in the Late Jurassic.     

南岭花山和姑婆山花岗岩基属印支期侵位:来自花岗岩熔体冷却-结晶和放射成因热计算的依据

通过对南岭西段花山和姑婆山花岗岩基地质-岩石地球化学特征研究,判明它们的侵位深度(5.5km)、围岩温度(196℃)及岩浆初始温度(950℃),建立起花山和姑婆山岩基的数学计算模型,计算得出:花山-姑婆山花岗岩熔体侵位后,其初始温度降低至结晶温度所需的时间(△tco1)分别为4.14 Ma(花山)和4.36Ma(姑婆山...     

Zircon LA-ICP-MS U-Pb dating and Sr-Nd isotope study of the Guposhan granite complex, Guangxi, China

Zircon U-Pb dating by the LA-ICP-MS method was applied to determining the ages of different units of the Guposhan granite complex, among which the East Guposhan unit is 160.8±1.6 Ma, the West Guposhan unit is 165.0±1.9 Ma, and the Lisong unit is 163.0±1.3 Ma in age. Much similarity in ages of the three units has thus proved that the whole Guposhan granite complex was formed in the same period of time. They were the products of large-scale granitic magmatism through crust-remelting in the first stage of the Middle Yanshanian in South China. However, the three units have differences both in petrology and in geochemistry. Besides the differences in major, trace and rare-earth elements, they are distinct in their Rb-Sr and Sm-Nd isotopic compositions. The East Guposhan unit and Lisong unit and its enclaves have a similar (87Sr/86Sr)i value of 0.7064 with an average of εNd(t)=-3.03, indicating that more mantle material was evolved in the magma derivation; whereas the West Guposhan unit has a higher (87Sr/86Sr)i value of 0.7173 but a lower εNd(t) value of -5.00, and is characterized by strong negative Eu anomalies and higher Rb/Sr ratios, suggesting that its source materials were composed of relatively old crust components and new mantle-derived components. In addition, an inherited zircon grain in the East Guposhan unit (GP-1) yielded a 206Pb/238U age of 806.4 Ma, which is similar to the ages of the Jiulin cordierite granite in northern Jiangxi and of the Yinqiao migmatic granite in Guangxi in the HZH granite zone. All this may provide new evidence for Late Proterozoic magmatism in the HZH granite zone.     

广西姑婆山地区矿产远景调查主要成果与进展

在广西姑婆山地区完成的矿产远景调查项目,在地层、岩浆岩、区域构造、物化探、矿产等方面取得重要进展。对地层进行了多重地层划分与对比,建立了非正式地层单位——开山砂岩;新发现三门．鹰阳关晋宁一加里东期NE向韧性剪切带,建立了区域构造格架,阐明了构造形成演化历史。通过对调查区地、物、化、遥等调查研究,发现一批矿产异常,提交新...     

富贺钟钨锡多金属矿集区成矿规律及成矿模式

成岩、成矿的时空关系及矿化特征综合研究表明,桂东北富贺钟地区钨锡多金属成矿主要与燕山期姑婆山复式岩体中晚期的细粒花岗岩有关,但成岩与成矿之间存在一定时差。区内矿化具有上锡下钨的垂向分带特征,细粒花岗岩侵入层位的不同制约了矿化类型及成矿元素组合。成矿作用过程中有幔源流体的参与,中泥盆统郁江组砂页岩和东岗岭组灰岩夹白云质灰岩之间的"硅-钙界面"对锡成矿具有重要的控制作用,也是锡矿就位的重要场所。细粒花岗岩体周缘的"硅-钙界面"附近是寻找锡多金属矿的远景地段。     

Intrusion and differentiation of granitic magma at a high level in the crust: the Puscao pluton, Lima Province, Peru

Regression surface techniques have been used on partial whole-rockchemical analyses from the Puscao pluton to establish the three-dimensionalnature of the chemical variations within this body, which wasemplaced at a depth of between 4 km and 8 km within the crust.Block diagrams produced by the computer program are consistentwith the hypothesis that during the period preceding the totalconsolidation of the magma, the pluton has undergone in situdifferentiation to give a layered structure. Statistical analysis confirms that there is a large scale variationwithin the pluton and that local variation, such as might beexpected to result from the contamination of the Puscao magmaby assimilated volcanic material, did not contribute significantlyto the overall variation. Evidence is presented which suggests that the layering withinthe Puscao pluton was disturbed as a result of the emplacementof the much later Cañhas pluton, and that this disturbancehas the form of a simple doming centred upon the site of thepresent Cañas intrusion.     

Geology, Geochronology, and Geodynamics of the Khan Bogd alkali granite pluton in southern Mongolia

The Khan Bogd alkali granite pluton, one of the world’s largest, is situated in the southern Gobi Desert, being localized in the core of the Late Paleozoic Syncline, where island-arc calc-alkaline differentiated volcanics (of variable alkalinity) give way to the rift-related bimodal basalt-comendite-alkali granite association. The tectonic setting of the Khan Bogd pluton is controlled by intersection of the near-latitudinal Gobi-Tien Shan Rift Zone with an oblique transverse fault, which, as the rift zone, controls bimodal magmatism. The pluton consists of the eastern and the western ring bodies and comes into sharp intrusive contact with rocks of the island-arc complex and tectonic contact with rocks of the bimodal complex. The inner ring structure is particularly typical of the western body and accentuated by ring dikes and roof pendants of the country island-arc complex. According to preliminary gravity measurements, the pluton is a flattened intrusive body (laccolith) with its base subsiding in stepwise manner northwestward. Reliable geochronologic data have been obtained for both plutonic and country rocks: the U-Pb zircon age of alkali granite belonging to the main intrusive phase is 290 ± 1 Ma, the ⁴⁰Ar/³⁹Ar ages of amphibole and polylithionite are 283 ± 4 and 285 ± 7 Ma, and the Rb-Sr isochron yields 287 ± 3 Ma; i.e., all these estimates are close to 290 Ma. Furthermore, the U-Pb zircon age of red normal biotite granite (290 ± 1 Ma) and the Rb-Sr age of the bimodal complex in the southern framework of the pluton are the same. The older igneous rocks of the island-arc complex in the framework and roof pendants of the pluton are dated at 330 Ma. The geodynamic model of the Khan Bogd pluton formation suggests collision of the Hercynian continent with a hot spot in the paleoocean; two variants of this model are proposed. According to the first variant, the mantle plume, after collision with the margin of the North Asian paleocontinent, reworked the subducted lithosphere and formed a structure similar to an asthenospheric window, which served as a source of rift-related magmatism and the Khan Bogd pluton proper. In compliance with the second variant, the emergence of hot mantle plume resulted in flattening of the subducted plate; cessation of the island-arc magmatism; and probably in origin of a local convective system in the asthenosphere of the mantle wedge, which gave rise to the formation of a magma source. The huge body of the Khan Bogd alkali granite pluton and related volcanic rocks, as well as its ring structure, resulted from the caldera mechanism of the emplacement and evolution of magmatic melts.     

Ar–Ar Ages of Hydrothermal Muscovite and Igneous Biotite at the Guposhan–Huashan District,Northeast Guangxi,South China: Implications for Mesozoic W–Sn Mineralization

The Guposhan–Huashan district is an important W–Sn–Sb–Zn–(Cu) metallogenic area in South China. It is located in the middle‐west segment of the Nanling Range. Granitoids in the Guposhan–Huashan district possess certain properties of A‐type or I‐type granites. The W–Sn–Sb–Zn mineralization in the district is closely associated with magma emplacement. Two igneous biotite and seven hydrothermal muscovite samples from skarn, veins and greisenization ores were analyzed by Ar–Ar methods. Two igneous biotite samples from fine‐grained quartz monzodiorite and fine‐grained biotite granite show plateau ages of 168.7 ± 1.9 Ma and 165.0 ± 1.1 Ma, respectively. Seven hydrothermal muscovite samples from ores yield plateau ages as two groups: 165 Ma to 160 Ma and 104 Ma to 100 Ma. These data suggest that the emplacement of fine‐grained granitoids in this district is coeval with the main phase magma emplacement, different from previous studies. The W–Sn–Sb–Zn mineralization took place in two stages, i.e. the Middle–Late Jurassic and early Cretaceous. W–Sn mineralization in the Guposhan–Huashan district is closely related to the magmatism, which was strongly influenced by underplating of asthenospheric mantle along trans‐lithospheric deep faults and related fractures.