江南隆起带中段新元古代花岗岩锆石U-Pb年代学和Hf同位素组成研究

对江南隆起带中段湘东西园坑岩体和赣西九岭岩体的LA-ICPMS锆石U-Pb年代学测定和LA-MC-ICPMS锆石Hf同位素原位分析测试表明:西园坑岩体形成于(804±3)Ma,赣西九岭岩体的年龄为(813±4)Ma和(823±2)Ma,均为新元古代花岗岩.上述三个样品的εHf(t)的加权平均值分别为0.68±0.71,...     

内蒙古乌拉特中旗乌兰地区石炭纪花岗闪长岩年代学及地球化学研究

利用锆石SHRIMP U-Pb法对乌拉特中旗乌兰地区花岗闪长岩进行年龄测试,得到的两个花岗闪长岩样品中锆石的加权平均年龄分别为(322.1±3.4)Ma和(323.4±3.4)Ma,为早石炭世。岩石地球化学及同位素地质年代学研究显示该花岗闪长岩为具有埃达克岩性质的I型花岗岩类,属准铝质-过铝质高钾钙碱性系列;富集Rb,Ba,Sr等大离子亲石元素和Th,U,Nd,Zr等高场强元素;为轻稀土富集型,轻、重稀土高度分异,轻稀土发生明显的分馏作用,铕异常不明显。岩体形成于活动大陆边缘同碰撞构造环境,是残留洋壳部分熔融所形成的基性岩浆与由古老片麻岩基底部分熔融所形成的中酸性岩浆发生混合作用的产物。     

高级变质作用对锆石U-Pb同位素体系的影响:胶东栖霞地区变质闪长岩锆石定年

文中对高级变质作用(高角闪岩相-麻粒岩相)条件下"干的"岩石体系中锆石U、Th、Ph行为进行了研究.样品为胶东栖霞地区太古宙变质基底的高角闪岩相-麻粒岩相变质闪长岩.矿物组合为单斜辉石+斜长石+钾长石+黑云母+石英.锆石呈近短轴状、等轴状和不规则状,阴极发光下具板状、杉树叶状、扇形结构,部分具封闭环带结构.锆石中存在斜...     

大别山鲁家寨花岗岩地球化学、锆石年代学和Hf同位素特征:扬子克拉通北东缘新元古代岩浆活动证据

对大别山造山带的鲁家寨花岗岩进行了锆石U-Pb年代学、锆石Hf同位素和岩石地球化学研究.锆石LA-ICP-MS U-Pb定年结果表明鲁家寨花岗岩形成于新元古代((816±17)Ma).鲁家寨花岗岩总体具有高硅(SiO2 69.13%～75.47%)、准铝-弱过铝(A/CNK=0.98～1.01)的化学组成特征.稀土元素...     

基于新测年资料的蓟县运动和燕山早期运动表现探讨:以深圳西部地区及东部大鹏半岛国家地质公园地区为例

近3年来在深圳西部及东部大鹏半岛国家地质公园等地,笔者等参加了地质路线调查研究和取样工作,先后采集了20组岩石同位素定年样品,采用新方法锆石U-Pb定年激光测试法测试,其中获得7个数据集中在1 007～897 Ma,首次发现中-新元古代蓟县纪-青白口纪,并基本可以证实蓟县运动(1 400～1 000 Ma)的存在;对中...     

蓬莱阁丹崖山安全监测与分析

丹崖山边坡稳定性是关系古文物蓬莱阁安全的关键问题。丹崖山边坡高差大、断层裂隙发育、岩体卸荷深度大,地质条件十分复杂,边坡在施工期和运行期的稳定性问题特别突出。该文介绍了丹崖山岩体加固后的监测布置,并对岩体表面变形趋势、空间分布形态、加固后变形趋势进行分析,通过对多点位移计、锚杆测力计、锚索测力计、表面裂缝计及地表变形等监测结果进行综合分析,得到边坡岩体的变形规律。     

高精度磁测在单县龙王庙地区铁矿调查中的应用

阐述了高精度磁测在单县龙王庙地区铁矿调查评价中的应用,高精度磁测的目的是分解早期1∶5万航磁异常,细致反映龙王庙地区磁异常的分布,为该区的铁矿调查评价和成矿预测提供了基础资料。以近年来的高精度磁测工作为基础,该区铁矿深部找矿取得了重大突破,勘查发现了大刘庄大型沉积变质型铁矿,并进行了富有价值的成矿预测,显示出了良好的地质效果。     

蓬莱阁丹崖山安全监测与分析

丹崖山边坡稳定性是关系古文物蓬莱阁安全的关键问题。丹崖山边坡高差大、断层裂隙发育、岩体卸荷深度大,地质条件十分复杂,边坡在施工期和运行期的稳定性问题特别突出。该文介绍了丹崖山岩体加固后的监测布置,并对岩体表面变形趋势、空间分布形态、加固后变形趋势进行分析,通过对多点位移计、锚杆测力计、锚索测力计、表面裂缝计及地表变形等监测结果进行综合分析,得到边坡岩体的变形规律。     

内蒙古北部乌日尼图地区阿仁绍布辉长岩体的形成时代、地球化学特征及成因

本文系统地报道了内蒙古北部乌日尼图地区阿仁绍布辉长岩的主量元素、微量元素和稀土元素特征,重点讨论了阿仁绍布辉长岩体的岩石成因、原始岩浆的源区特征及其地质意义。研究结果表明,阿仁绍布辉长岩体SiO2含量为49.62%,Al2O3为17.34%,CaO为8.94%,TiO2为1.44%,P2O5为0.26%;岩石富集LILE、亏损HFSE。岩体的Mg#值（0.28～0.68,平均为0.52）较高,反映原始岩浆具幔源原生玄武岩浆特征,在上升过程中经历的结晶分异程度较低。U-Pb锆石年龄测定结果为309±2Ma,代表了阿仁绍布辉长岩体的结晶年龄,为晚石炭世。计算出石英结晶温度为928℃,斜长石结晶温度为1206℃;岩浆冷凝矿物共结晶时的深度大于10km,其结晶条件代表岩体侵位时的物理环境,是在较深的岩浆房中结晶的。阿仁绍布辉长岩具有大陆边缘弧的地球化学特征,可能反映在岩浆形成之前,地幔源区发生了俯冲交代富集作用。     

Two episodes of the Indosinian thermal event on the South China Block: Constraints from LA-ICPMS U–Pb zircon and electron microprobe monazite ages of the Darongshan S-type granitic suite

The Darongshan granitic suite (~ 10,000 km²) consists of five major units (Taima, Nadong and Jiuzhou plutons, and Pubei and Darongshan batholiths) typical of peraluminous S-type granitoids containing abundant granulite inclusions in the Cathaysia block, South China. Six samples from these plutons and batholiths have been investigated using both LA-ICPMS U–Pb age dating on zircon cores and EMP U–Th–Pb chemical age dating on monazite cores and rims. LA-ICPMS zircon results give similar major age populations ranging between 260 ± 3 and 250 ± 3 Ma for all units, with apparent older age peaks concentrated at 1020, 800, 430 and 330 Ma. On the other hand, EMP monazite results yield younger ages of 231–229 Ma for Nadong, Taima, Pubei and Darongshan and 224 Ma for Jiuzhou samples, with older age groups of 264 Ma for Taima and 256–250 Ma for Pubei units. Since the older monazite ages are similar to the majority of zircon ages, the latter are considered as inherited ages. Further because such zircon ages are similar with the emplacement time of the Emeishan large igneous province in western South China, they likely reflect the timing of metamorphism for the included fragments of granulitic crusts that had been formed by invasion of the Emeishan plume. The younger monazite ages, as present for all plutons and batholiths in the entire Darongshan area, are taken as the formation age of the host granites. Combining U–Pb zircon and EMP monazite ages known for Permo-Triassic high temperature and high pressure metamorphic rocks and granites in the Indochina block (e.g., the Kannack Complex of the Kontum massif), it is suggested that the Indosinian thermal activity had set records over both the Indochina (plus Simao) and South China blocks in two main episodes, one is 260–250 Ma and the other is 231–229 Ma. One plausible explanation is that these two blocks were one united continent before the Emeishan plume activity and an opening was triggered by this plume at ~ 260 Ma. Due to forces of the approaching Sibumasu block, both the South China and Indochina blocks were amalgamated again at ~ 230 Ma. We, therefore, advocate that double subduction of the plume-triggered oceanic crusts in opposite directions is responsible for the generation of the Darongshan granitic suite in the South China block and its counterpart in the Indochina block.