青海都兰东北部哈莉哈德山花岗片麻岩LA-ICP-MS锆石U-Pb年龄及构造意义

青海都兰东北部哈莉哈德山花岗片麻岩原岩为具有S-型花岗岩特征的酸性侵入岩。来自该片麻岩的20粒锆石的LA-ICP-MS U-Pb年龄测定表明,该片麻岩的原岩花岗岩岩浆于约950Ma侵位结晶,岩浆物源源区存在中—新元古代的物质成分。正确甄别哈莉哈德山花岗片麻岩的变质围岩是否隶属于全吉地块的达肯大坂岩群,是理解全吉地块与柴达木地块在新元古代时期构造演化关系的关键。     

黑龙江省羊鼻山铁钨矿床中钨矿成因及物质来源

黑龙江省双鸭山市羊鼻山铁钨矿床处于中亚造山带东段的佳木斯地块中部。兴东群大盘道组变质岩系为矿区主要赋矿地层,铁矿矿体呈层状、似层状赋存于大盘道组第一岩段,白钨矿矿体呈透镜状和脉状产于铁矿矿体底板围岩中,受片麻状花岗岩与大盘道组大理岩的接触带控制;主要含矿岩石为石榴石矽卡岩和透辉石矽卡岩,钨矿石中主要金属矿物为磁黄铁矿和白钨矿,并含少量磁铁矿、黄铁矿、黄铜矿、闪锌矿、锡石、毒砂和辉钼矿。含钨石英脉中δ¹⁸O_水值为3.6‰~7.5‰,δD值为-120.9‰~-66.2‰,表明其成矿流体以岩浆水为主。矽卡岩中与白钨矿共生的金属硫化物δ³⁴S值为16.1‰~18.1‰,²⁰⁶Pb/²⁰⁴Pb值为17.879~18.863,²⁰⁷Pb/²⁰⁴Pb值为15.537~15.603,²⁰⁸Pb/²⁰⁴Pb值为38.202~38.544,表明金属硫化物中的硫和铅主要来源于地层与地壳重熔型岩浆。结合钨矿成矿地质特征,认为羊鼻山铁钨矿床中钨矿的成因类型应属矽卡岩型。     

摩天岭褶皱带及邻区晚前寒武纪板块构造初析

摩天岭褶皱带位于扬子地台西北缘,主要由中、晚元古宇“碧口群”火山、沉积杂岩系组成。笔者认为:该套杂岩系在刘家坪—铜钱韧性剪切带以南,是一套构造混杂岩,属中晚元古宙“碧口”古洋盆消减、关闭过程中形成的产物;在该剪切带以北,碧口杂岩系则主要由一套弧前盆地杂砂岩系和一套钙碱性火山岩系组成,后者属喷发在以鱼洞子群为基底的南秦岭古陆南缘之上的岛弧火山岩系。晚元古宙末,由于介于南秦岭古陆与扬子古陆之间的碧口古洋盆关闭,最终形成了扬子古陆北缘晚元古宙碰撞型造山带。摩天岭褶皱带则属该碰撞造山带的超迭壳楔和碰撞混杂岩单元部分。     

摩天岭地块及东南缘地质构造演化与成矿作用

摩天岭地块处于西秦岭造山带南部,为一由玛曲－略阳断裂、岷江断裂及青川－古城断裂所分割的三角形地块,经历了晋宁期－喜马拉雅期多阶段地史演化,与扬子大陆多次分离和拼合。经过晚印支造山运动、燕山期伸展和喜马拉雅期逆冲推覆运动,铸成了摩天岭东南缘现今的地质构造景观。漫长而复杂的地质构造演化过程,为金及多金属矿产的形成提供了有利条件。     

Late- and post-Variscan cooling and exhumation history of the northern Rhenish massif and the southern Ruhr Basin: new constraints from fission-track analysis

Apatite fission-track analyses were carried out on outcrop and core samples from the Rhenish massif and the Carboniferous Ruhr Basin/Germany in order to study the late- and post-Variscan thermal and exhumation history. Apatite fission-track ages range from 291±15 Ma (lower Permian) to 136±7 Ma (lower Cretaceous) and mean track lengths vary between 11.6 m and 13.9 m, mostly displaying unimodal distributions with narrow standard deviations. All apatite fission-track ages are younger than the corresponding sample stratigraphic age, indicating substantial post-depositional annealing of the apatite fission-tracks. This agrees with results from maturity modelling, which indicates 3500–7000 m eroded Devonian and Carboniferous sedimentary cover. Numerical modelling of apatite fission-track data predicts onset of exhumation and cooling not earlier than 320 Ma in the Rhenish massif and 300 Ma in the Ruhr Basin, generally followed by late Carboniferous–Triassic cooling to below 50–60°C. Rapid late Variscan cooling was followed by moderate Mesozoic cooling rates of 0.1–0.2°C/Ma, converting into denudation rates of <1 mm/a (assuming a stable geothermal gradient of 30°C/km). Modelling results also give evidence for some late Triassic and early Jurassic heating and/or burial, which is supported by sedimentary rocks of the same age preserved at the rim of the lower Rhine Basin and in the subsurface of the Central and Northern Ruhr Basin. Cenozoic exhumation and cooling of the Rhenish massif is interpreted as an isostatic response to former erosion and major base-level fall caused by the subsidence in the lower Rhine Basin.     

Morphological and structural analysis in the Anaga offshore massif, Canary Islands: fractures and debris avalanches relationships

As part of the ‘National Hydrographic and Oceanographic Research Plan for the Spanish Exclusive Economic Zone’, multibeam bathymetry and seismic reflection profiles were obtained in the Canary Islands aboard the R/V Hespérides. The submarine flanks of the Anaga offshore extension of Tenerife Island are here studied to analyze its geomorphology. In the north sector of the Anaga submarine massif, the extension of the Anaga Debris Avalanche has been mapped for the first time, and a volume of 36 km³ was calculated. The relationship between the Anaga and Orotava Debris Avalanches is also described. Faulting has been recognized as a key process for the occurrence of debris avalanches and the growth of volcanic lineaments. Moreover, faulting affects previous structures and the channelling of debris flows. Structural analysis shows the typical radial pattern of an oceanic island. In addition, a NE-SW dominant direction of faulting was obtained, consistent with the Tenerife Island structural trend seen in the Anaga Massif and Cordillera Dorsal. NW-SE and E-W are two other main trends seen in the area. Special interest is manifest in two long faults: ‘Santa Cruz Fault’ bounds the southern edge of Anaga offshore Massif with a length of 50 km and a direction that changes from NE-SW to almost E-W. The Güimar Debris Avalanche was probably channeled by this fault. The ‘Guayotá Fault’ was recognized in several seismic profiles with a N-S direction that changes towards NW-SE at its southern end. This fault affects the more recent sediments with a vertical offset of 25–30 m, along 60~km. It has been interpreted as a transpressive strike-slip fault.ZEE Working Group**F. Carrillo^a, C. Maté^a, M. Ballesteros^b, M. Vaquero^b, J. Martín-Dávilla^c and J.A. Marín^caInstituto Hidrográfico de la Marina. Cádiz^bInstituto Español de Oceanografía. Madrid.^cReal Observatorio de la Armada. S. Fernando, Cádiz.     

胶北粉子山群和荆山群三叠纪变质变形记录:金红石U-Pb年代学证据

胶北地块粉子山群和荆山群是华北克拉通的重要组成部分,其变质变形作用过程是全面认识华北克拉通性质与演化的关键。前人对粉子山群和荆山群变质变形年代研究的测试对象主要为锆石,报道的年代学数据多集中于1.8~1.9Ga,认为变质变形作用的时代为古元古代。本文通过对采集自胶北粉子山群和荆山群的2个石榴云母片岩和2个云母片岩样品中独居石及金红石的U-Pb同位素年代测定,揭示了胶北粉子山群和荆山群不仅经历了古元古代(1869±16~1864±14 Ma)变质事件的改造,而且还经历了三叠纪(215.1±4.2~217.8±6.3Ma)变质变形事件的叠加。通过金红石中Zr温度计计算得出215.1±4.2 Ma,217.7±2.7 Ma和217.8±6.3 Ma的U-Pb年龄对应温度分别为:658℃,667℃和680℃。表明胶北地块部分卷入了三叠纪苏鲁-大别超高压变质带的俯冲-碰撞造山过程,并遭受了角闪岩相变质作用叠加。     

大别山东北缘桐城高压-超高压变质带的构造解析及其对郯庐断裂带的制约

通过对郯庐断裂带南段桐城地区高压-超高压变质带详细的岩石学和构造学研究,将研究区从空间结构上划分为三个构造单元:上部低温-高压单元、中部中温-高压单元和下部超高压单元。根据研究区多期构造变形分析,共识别出了五期有区域构造地质学含义的事件(D_1-D_5):D_1代表高压-超高压变质岩中-晚三叠世同碰撞早期折返过程;D_2表征了高压-超高压变质岩晚三叠世同碰撞晚期折返过程;D_3记录了早白垩世中大别变质核杂岩的形成,也即整个中国东部晚中生代大规模伸展构造在研究区的表现;D_4可能标志着郯庐断裂走滑构造对高压-超高压造山带的叠加;D_5表现为脆性正断作用,控制了晚白垩世-古近纪潜山半地堑盆地的形成。这些结果表明了研究区所经历构造演化的复杂性,其构造几何形态很难用郯庐断裂左行平移南大别超高压变质岩来解释,也不支持桐城地区存在巨大走滑作用的证据。