桐柏山L构造岩的构造特征与形成环境探讨

桐柏山太白顶、殷店和天河口一带,发育有大量的L构造岩,拉伸线理极其发育,面理较弱,线理产状向南东东倾伏,倾伏角为1°～20°。桐柏山L构造岩具有以下主要特征：在三维空间上,L构造岩强烈发育杆状构造,这种“杆”状构造是由大量沿X轴方向定向排列连在一起的椭球体矿物构成的,其变形机制主要为石英的颗粒边界迁移和长石的位错蠕变,形成的平均压力为0.59GPa,平均温度为550 ℃～600 ℃,形成于中-高温-中压环境,变质相为高绿片岩相到低角闪岩相,形成深度大致在15～20 km,属于中地壳的产物。L构造岩在桐柏山的发现可能反映了桐柏山造山带中桐柏杂岩岩块相对两侧榴辉岩岩片具有近东西向挤出构造的特征。     

Permo-Carboniferous Radiolarians from the Wupata''''erkan Group,Western South Tianshan, Xinjiang, China

1 IntroductionThe Wupata'erkan Group, also called Wupata'erkanFormation (Wang et al., 1990), in the western SouthTianshan, China (Fig. 1), mainly comprises gray and darkgray fine-grained clastic rocks, interlayered with medium-acidic volcanic rocks (andesite and quartz porphyry),carbonates, cherts and variegated tuffaceousconglomerates. The chert in the formation was firstly foundin our field trip along sections of the Qiqi'erjianakesu Riverand Kekebiele Daban. Deformation of the group is…     

东海陆架盆地南部中生界沉积模式

在沉积相综合分析基础之上,通过地震相分析的手段明确了东海陆架盆地南部中生界的沉积特征;结合古地理背景分析,建立了该区侏罗纪和白垩纪的沉积模式。侏罗纪时雁荡低凸起和瓯江凹陷均未形成,闽江凹陷和基隆凹陷连为一体,物源来自浙闽隆起区,发育滨浅海沉积体系,火山作用较为强烈。白垩纪晚期-古新世,随着太平洋板块俯冲角度的加大,浙闽隆起区发生裂陷,雁荡低凸起形成。西部的瓯江凹陷沉积了一套陆相的冲积扇-河流-三角洲-湖泊沉积体系;由于此间台北低凸起尚未起到分割作用,东部的闽江凹陷与基隆凹陷仍然连为一体,物源来自浙闽隆起带和台北水下火山岩带,发育滨浅海沉积体系,火山作用影响强烈。     

深部矿产资源立体地球化学勘查方法技术体系

深部矿产资源的勘查是战略性矿产资源勘查的一个重要方面。找矿实践证明，化探方法技术在矿产勘查乃至深部找矿中发挥了重要的、不可或缺的作用。找矿工作的不断深入和找矿难度的不断加大，促使化探方法技术不断的发展和完善，在传统方法技术的基础上，研发出了许多新的方法技术。本文从方法论和系统论的角度出发，对现有的找寻深部隐伏矿盲矿的有效化探方法技术进行了系统的归纳和总结，提出了立体地球化学勘查方法技术体系的概念，将立体地球化学勘查方法技术划分为地面地球化学测量方法技术和地下地球化学测量方法技术，建立了深部矿产资源立体地球化学勘查方法技术体系。不同的方法技术有不同的优势和不同的适用条件，实际工作中应当根据不同的勘查阶段，不同的勘查目的和不同的地质地球化学条件选择不同的立体方法技术组合才能发挥出最大效益，取得最大效果。     

辽东石庙沟岩体岩石地球化学特征、锆石U-Pb年龄、Hf同位素及其地质意义

辽东石庙沟地区位于华北陆块东部的辽吉造山/活动带上,该带经历了十分复杂的构造演化过程,记录了多期岩浆-构造-变质事件。石庙沟岩体为花岗斑岩,富SiO₂、Na₂O和K₂O,贫CaO、MgO及Al₂O₃,亏损高场强元素（Nb、Ti、Ta、P）,富集大离子亲石元素（K、Rb、Ba、U）,A/CNK值大于1,REE配分曲线呈"海鸥"式分布,以具有显著的负Eu异常为特征,高Ga/Al值,与典型A型花岗岩特征一致。花岗斑岩中锆石的LA-ICP-MS U-Pb测年结果表明其成岩年龄为（123.0±1.6）Ma,为早白垩世。锆石Hf同位素分析表明,ε_Hf（t）值均为负值,介于-15.72~-12.85之间,平均值为-14.14,二阶段模式年龄（T_DM2）在2 164~1 989 Ma之间,平均为2 067 Ma,反映源岩以大陆壳成分为主。结合花岗斑岩高SiO₂,低Mg、Co、Cr、Ni,且富集LREE和LILE,亏损HFSE等特征,表明早白垩世花岗斑岩岩浆应为大陆地壳物质熔融的产物。根据年代学和岩石地球化学研究认为,早白垩世花岗斑岩是古太平洋板块向欧亚大陆板块俯冲所形成的活动大陆边缘弧花岗岩。研究区早白垩世花岗斑岩的形成主要受太平洋构造域的影响,形成环境受板块俯冲造山后伸展作用和下地壳拆沉作用的联合制约,是辽东地区岩石圈减薄的直接证据。     

华北地台北缘西段主要成矿系统分析

研究了华北地台北缘地质演化、构造分区, 从南到北依次为乌拉山-色尔腾山-大青山陆内隆起区、东升庙-渣尔泰山陆内裂陷区、狼山-石哈河陆缘隆起区、霍各乞-白云鄂博陆缘裂陷区、白乃庙-白银都西隆起裂陷带、温都尔庙-爱力格庙裂陷带、苏左旗-锡林浩特槽内隆起区.分析了陆缘基底建造和裂谷沉积建造, 划分出裂谷裂陷期和沉降期沉积.研究了成矿系统, 以成矿物质来源的同一性和继承性划分出3个成矿系统: (1) 变质岩金矿成矿系统, 以绿岩建造为物源基础, 有多种矿床类型组合, 主要产于古陆隆起带的变质岩区. (2) 海相火山细碧岩及喷流沉积成矿系统, 主要产于裂谷裂陷期形成的火山岩建造中, 与火山活动岩浆同期的热水喷流有关, 有铜、铅、锌多金属矿床. (3) 碱性-碳酸岩及喷流叠生成矿系统, 产于白云鄂博裂谷早期碱性-碳酸岩火山岩中, 其中伴随高温硅钾热水喷流沉积, 形成稀有-稀土-铁叠生矿床.主、东矿床新生代以来经受了强烈风化剥蚀, 并有冲积富集现象.      

辽宁清河断裂以北新太古代变质表壳岩的发现及其地质意义

通过详实的地质填图,在辽宁开原地区清河断裂以北新发现一套变质表壳岩组合,主要岩性为斜长角闪岩、黑云角闪斜长变粒岩、黑云角闪斜长片麻岩、浅粒岩及角闪石岩的岩石组合,与红透山岩组基本可以对比。岩石地球化学特征表明,其原岩主要为一套中、中基性的火山岩建造,形成于岛弧环境。该套岩石组合普遍发生强烈的构造变形作用,常见构造样式包括透入性片麻理、石香肠构造、变质分异条带、肠状褶皱等一系列的固态流变构造。对该套变质表壳岩组合中的斜长角闪岩进行LA-ICP-MS锆石U-Pb测年,结果表明其形成于(2 524±18)Ma,变质年龄为(2 477±21)Ma,从形成到发生变质相隔约为47Ma。该套变质表壳岩组合的发现,表明了清河断裂以北也曾存在太古宙结晶基底,清河断裂与寇河断裂之间的区域在构造环境上与清原地区一样,均属于新太古代绿岩带。     

Late Mesozoic compressional to extensional tectonics in the Yiwulüshan massif,NE China and their bearing on the Yinshan–Yanshan orogenic belt: Part II: Anisotropy of magnetic susceptibility and gravity modeling

Granitoids play an important role in deciphering both crustal growth and tectonic evolution of Earth. In the eastern end of the Yinshan–Yanshan belt of North China Craton, the Yiwulüshan massif is a typical region that presents the tectonic evolution features of this belt. Our field work on the host rocks has demonstrated two phases of opposite tectonics: compressional and extensional, however, the deformation is almost invisible in the intrusive rocks. To improve the understanding of the tectonic evolution of the Yiwulüshan massif and the Late Mesozoic tectonics of East Asia, a multidisciplinary study has been carried out. In this study, anisotropy of magnetic susceptibility (AMS) and gravity modeling have been applied on these Jurassic plutons (Lüshan, Jishilazi and Guanyindong), which intrude into the Yiwulüshan massif. According to laboratory measurements and microscopic observations on thin sections, the AMS of the Yiwulüshan massif is characterized by secondary fabrics, indicating that the intensive post solidus deformation has reset the (primary) magmatic magnetic fabrics. A relatively gentle NW dipping magnetic foliation has been identified with two distinct groups of magnetic lineations of N34°E and N335°E orientations, namely L_M1 and L_M2, relatively. Gravity modeling reveals a southward thinning of the massif with a possible feeding zone rooted in the northern part of the massif. Integrating all results from structural observation, geochronological investigation, AMS measurement and gravity modeling, two tectonic phases have been identified in the Yiwulüshan massif, posterior to the Jurassic (180–160 Ma) magmatism in the Yinshan–Yanshan area. The early one concerns a Late Jurassic–Early Cretaceous (~ 141 Ma) compressional event with a top-to-the-south to southwest sense of shear. The second one shows an Early Cretaceous (~ 126 Ma) NW–SE ductile extensional shearing. At that time, sedimentary basins widened and Jurassic plutons started to be deformed under post solidus conditions. In fact, the NW–SE trend of the maximum stretching direction is a general feature of East Asian continent during Late Mesozoic.     

长乐-南澳韧性剪切带走滑特征探讨

长乐-南澳韧性剪切带可能是在碰撞造山缝合带基础上发育的,其走滑特性严格受闽台微大陆与闽浙中生代火山弧碰撞过程中碰撞动力学的制约。岩石韧性组构和糜棱岩变形的微构造研究表明,碰撞前期走滑为左行。在早垩世晚期(100-120Ma)的主碰撞期和以伸展作用为主的碰撞后期,该带以右行为主,这种右行走滑一直持续至今。发育韧性剪切带的闽台微大陆(或称平潭-东山带)原始位置可能比现今更靠南,这是属于几百公里的漂移位移而不是剪切位移。     

Spatial coupling relationships of gas hydrate formation in the Tibetan Plateau

At present, gas hydrates are known to occur in continental high latitude permafrost regions and deep sea sediments. For middle latitude permafrost regions of the Tibetan Plateau, further research is required to ascertain its potential development of gas hydrates. This paper reviewed pertinent literature on gas hydrates in the Tibetan Plateau. Both geological and ge- ographical data are synthesized to reveal the relationship between gas hydrate formation and petroleum geological evo- lution, Plateau uplift, formation of permafrost, and glacial processes. Previous studies indicate that numerous residual basins in the Plateau have been formed by original sedimentary basins accompanied by rapid uplift of the Plateau. Ex- tensive marine Mesozoic hydrocarbon source rocks in these basins could provide rich sources of materials forming gas hydrates in permafrost. Primary hydrocarbon-generating period in the Plateau is from late Jurassic to early Cretaceous, while secondary hydrocarbon generation, regionally or locally, occurs mainly in the Paleogene. Before rapid uplift of the Plateau, oil-gas reservoirs were continuously destroyed and assembled to form new reservoirs due to structural and thermal dynamics, forcing hydrocarbon migration. Since 3.4 Ma B.P., the Plateau has undergone strong uplift and extensive gla- ciation, periglacier processes prevailed, hydrocarbon gas again migrated, and free gas beneath ice sheets within sedi- mentary materials interacted with water, generating gas hydrates which were finally preserved under a cap formed by frozen layers through rapid cooling in the Plateau. Taken as a whole, it can be safely concluded that there is great temporal and spatial coupling relationships between evolution of the Tibetan Plateau and generation of gas hydrates.