腾冲地区与燕山期花岗岩有关的矿床成矿系列

腾冲地区岩浆-热液成矿作用形成了东、中、西三个矿带,以及滇滩-大硐厂-红岩头铅锌锡铁硅灰石矿、铁窑山-小龙河锡钨铁铅锌矿两个重要矿集区。本文以前人研究资料为基础,按矿床成矿系列理论研究方法,厘定了该地区与燕山期花岗岩有关的矿床成矿系列及亚系列,系统总结了该地区与燕山期花岗岩有关的矿产资源时空分布规律,研究结果表明燕山期是本地区最为重要的岩浆-热液成矿作用时期,该地区锡、铅、锌、铁、铜、钨、金、银、硫铁矿、硅灰石、萤石、宝石、云母、红柱石、稀土及稀有金属矿等矿产主要与燕山期花岗岩有关,构成了特定的与燕山期花岗岩有关的矿床成矿系列,并根据花岗岩分带、矿床空间分布、矿化组合、成矿时代的不同,进一步分为3个矿床成矿亚系列,总结了矿床成矿亚系列特点,分析了该地区的找矿潜力,指出了找矿远景区,深化了对腾冲地区锡(钨)、铅锌、铁、硅灰石、铜等矿产成矿规律认识,为今后在该地区从事地质找矿、教学和科研等方面提供参考。     

西准噶尔南部晚古生代侵入岩特征和构造背景

西准噶尔地区南部达拉布特断裂两侧广泛发育晚古生代花岗岩类,其锆石U-Pb年龄范围为337~276 Ma,属早石炭世-早二叠世.基于前人相关研究资料和成果,总结区内花岗岩类的岩石学、地球化学特征,认为：①岩石类型从早到晚由中性的闪长岩向酸性的花岗岩及碱长花岗岩转变.相应地,成因类型由埃达克岩质花岗岩→岛弧I型花岗岩→A型花岗岩.②岩石系列从早到晚由钙碱性向高钾钙碱性及后期钾玄岩系列转变.相应地,Na2O/K2O比值亦由大于1向小于1转变.③从早到晚区内花岗岩类的∑REE、δEu、L/H及Sr、Yb含量均呈规律性变化.并且相对富集LILE,亏损HFSE和不同程度亏损Nb、Ta.④均具有高正εNd（t）、低（87Sr/86Sr）i值和Nd模式年龄较小的特征.⑤在构造环境判别图解上,区内花岗岩从早到晚显示出由碰撞挤压向后碰撞伸展体制转换的趋势.上述几点说明区内花岗岩可能主要产出于后碰撞挤压-伸展转换和伸展拉张的构造背景,并且早阶段的岩浆活动可能与俯冲-碰撞背景下的俯冲板片断离密切相关.     

三元长石地质温度计及其在我国粤西花岗岩中的应用

根据Green et al(1986)提出的三元长石温压计公式,以长石三元固溶体和矿物相平衡为基础,通过热力学推导,建立了联立方程法和迭代法两种计算三元长石温度的方法.根据联立求解可获得TAb-Or、TOr-An、TAb-An三个温度值,迭代法求解可获得TAb、TOr、TAn三个温度值.因此,一个样品可计算出6个温度数据.选择粤西地区有代表性的18个花岗岩体,按混合岩建造→深熔花岗岩建造→岩浆建造南岭系列花岗岩→岩浆建造长江系列花岗岩的顺序,进行三元长石法的温度计算,所得到的相应各建造和系列花岗岩的上限温度为755℃→766℃→865℃→970℃;下限温度为664℃→665℃→775℃→814℃,亦即上下限温度都逐渐升高,其规律性与地质和地球化学研究结果完全一致,体现了三元长石地质温度计的可靠性和准确性.     

川西甲基卡矿床外围中酸性侵入岩LA-ICP-MS锆石U-Pb年龄及地球化学特征

在川西甲基卡矿床外围新发现了建巴村中酸性侵入岩体,为了探讨其形成时代、成岩构造背景及其成矿条件,开展了LA-ICP-MC锆石U-Pb年代学和地球化学特征研究.结果表明:该岩体的结晶年龄为(211.8±1.0)Ma;岩石属于钙碱性-高钾钙碱性准铝质中酸性侵入岩系列,具有I型花岗岩类的特征,其物质来源可能为壳源物质与幔源物质部分熔融.地球化学特征表明其形成于后碰撞环境,与此时期内川西地区的区域性岩浆活动相对应.建巴村岩体的构造位置及岩浆活动特征指示其可能不具备形成伟晶岩矿床的条件.     

粤东铁坑坳铁锡多金属矿床锆石及锡石U-Pb年代学、Nd-Hf同位素特征及其意义

铁坑坳铁锡多金属矿床位于粤东莲花山断裂带西部,矿区出露的花岗岩类主要有粗粒二长花岗岩和花岗闪长斑岩,花岗质岩石与碳酸盐岩的接触带中发育铁锡多金属矿化。该矿区的成岩成矿时代尚不明确,成矿与哪一种岩体具有成因上的联系也不清楚。文章选择与铁锡多金属矿体相关的花岗岩类的锆石和块状矿石中的锡石,首次开展LA-ICP-MS U-Pb定年和Nd-Hf同位素研究。结果表明：粗粒二长花岗岩和花岗闪长斑岩的锆石U-Pb年龄分别为（132±1） Ma （n=24,MSWD=0.78）和（94±1） Ma （n=25,MSWD=1.80）;块状矿石中锡石U-Pb年龄为（130±3） Ma （n=36,MSWD=0.62）,成矿时代与粗粒二长花岗岩形成时代基本一致,均形成于早白垩世;粗粒二长花岗岩的锆石ε_Hf （t）变化于-4.9~-0.1,平均值为-2.8,地壳Hf模式年龄T_DMC=1192~1497 Ma,平均值为1366 Ma,全岩ε_Nd （t）值介于-8.8~-8.7,Nd同位素二阶段模式年龄T_DM2变化于1630~1642 Ma;花岗闪长斑岩的锆石ε_Hf （t）变化于-5.7~-2.9,平均值为-4.4,地壳Hf模式年龄T_DMC=1342~1523 Ma,平均值为1440 Ma,全岩ε_Nd （t）值介于-5.4~-4.9,Nd同位素二阶段模式年龄T_DM2变化于1291~1332 Ma。Nd-Hf同位素综合研究表明,粗粒二长花岗岩的源区物质主要来自于中元古代地壳,有少量幔源组分或新生地壳的加入,花岗闪长斑岩的源区物质中幔源组分或新生地壳的混入比例高于粗粒二长花岗岩。     

Dehydration melting of micas in the Chilka Lake Khondalites: The link between the metapelites and granitoids

Garnet-sillimanite gneisses, locally known as khondalites, occur abundantly in the Chilka Lake granulite terrane belonging to the Eastern Ghats Proterozoic belt of India. Though their chemistry has been modified by partial melting, it is evident that the majority of these rocks are metapelitic, with some tending to be metapsammitic. Five petrographically distinct groups are present within the khondalites of which the most abundant group is characteristically low in Mg:Fe ratios — the main chemical discriminant separating the five groups. The variations in Mg:Fe ratios of the garnets, biotites, cordierites, orthopyroxenes and spinels from the metapelites are compatible with those in the bulk rocks. A suite of granitoids containing garnet, K-feldspar, plagioclase and quartz, commonly referred to as leptynites in Indian granulite terranes, are interlayered with khondalites on the scale of exposures; in a few spots, the intercalated layers are thin. The peraluminous character of the leptynites and presence of sillimanite trails within garnets in some of them suggest derivation of leptynites by partial melting of khondalites. Here we examine this connection in the light of results derived from dehydration melting experiments of micas in pelitic and psammitic rocks. The plots of leptynites of different chemical compositions in a (MgO + FeO)-Na₂O-K₂O projection match the composition of liquids derived by biotite and muscovite dehydration melting, when corrected for co-products of melting reactions constrained by mass balance and modal considerations. The melt components of the leptynites describe four clusters in the M-N-K diagram. One of them matches melts produced dominantly by muscovite dehydration melting, while three clusters correspond to melting of biotite. The relative disposition of the clusters suggests two trends, which can be correlated with different paths that pelitic and psammitic protoliths are expected to generate during dehydration melting. Thus the leptynites evidently represent granitoids which were produced by dehydration melting in metapelites of different compositions. The contents of Ti, Y, Nb, Zr and Th in several leptynites indicate departures from equilibrium melt compositions, and entrainment of restites is considered to be the main causative factor. Disequilibrium in terms of major elements is illustrated by leucosomes within migmatites developed in a group of metapelites. But the discrete leptynites that have been compared with experimental melts approach equilibrium melt compositions closely.     

新疆北部花岗岩类的稀土特征

新疆北部的改造系列花岗岩演化由斜长花岗岩阶段、钾长花岗岩阶段至碱长花岗岩阶段,其稀土配分组成递降曲线簇.新疆北部的同熔型花岗岩类稀土配分基本为轻稀土富集型,具Eu负异常,有递增曲线簇和递降曲线簇两种情况.深源碱性系列轻重稀土比值大、Eu负异常一般不显著.文中还叙述了新疆北部的幔分异系列花岗岩类及一些古老花岗岩的稀土特征.     

Structure of the Basin and Ridge System West of New Caledonia (Southwest Pacific): A Synthesis

Complementary to previous work mainly based on seismic interpretation, our compilation of geophysical data (multibeam bathymetry, gravity, magnetic and seismic) acquired within the framework of the ZoNéCo (ongoing since 1993) and FAUST (1998–2001) programs enables us to improve the knowledge of the New Caledonia Basin, Fairway Basin and Fairway Ridge, located within the Southwest Pacific region. The structural synthesis map obtained from geophysical data interpretation allows definition of the deep structure, nature and formation of the Fairway and New Caledonia Basins. Development of the Fairway Basin took place during the Late Cretaceous (95–65 Ma) by continental stretching. This perched basin forms the western margin of the New Caledonia Basin. A newly identified major SW–NE boundary fault zone separates northern NW–SE trending segments of the two basins from southern N–S trending segments. This crustal-scale fault lineament, that we interpret to be related to Cretaceous-early Cainozoic Tasman Sea spreading, separates the NW–SE thinned-continental and N–S oceanic segments of the New Caledonia Basin. We can thus propose the following pattern for the formation of the study area. The end of continental stretching within the Fairway and West Caledonia Basins ( 65–62 Ma) is interpreted as contemporaneous with the onset of emplacement of oceanic crust within the New Caledonia Basin’s central segment. Spreading occurred during the Paleocene (62–56 Ma), and isolated the Gondwanaland block to the west from the Norfolk block to the east. Finally, our geophysical synthesis enables us to extend the structural Fairway Basin down to the structural Taranaki Basin, with the structural New Caledonia Basin lying east of the Fairway Basin and ending further north than previously thought, within the Reinga Basin northwest of New Zealand.