辽南金州拆离断层带中花岗质岩石的变形:显微构造、组构与年代学分析

花岗岩(脉)在中下地壳韧性剪切带中普遍发育,如何正确鉴别剪切带中剪切前、剪切期及剪切后花岗岩(脉)以及正确理解剪切过程中构造变形与岩浆作用之间的关系一直是一个重要课题。本文以辽南金州拆离断层带为研究对象,选取中部地壳伸展作用过程中具有不同变形表现的花岗岩(脉)开展宏观-微观构造观察、石英EBSD组构分析及锆石LA-ICP-MS年代学测试等工作,从而进一步丰富构造-岩浆关系判别准则。剪切前花岗岩(脉)多变形强烈且具有后期固态变形叠加在早期高温岩浆组构之上的特点,而剪切期的花岗岩由于侵位的时间不同,岩石的变形程度也会不同。剪切晚期侵入的岩脉遭受了较弱的晶内塑性变形,而剪切早期的岩脉可以显示岩浆流动或结晶后高温至中温固态变形。从组构特点上看,剪切前和剪切期花岗质岩石石英c轴组构大多表现为中高温组构叠加有低温组构的特点。剪切后的花岗质岩石仅发生微弱的晶内变形或未变形而显示低温或无规律的组构特征。对五个典型的样品进行年代学测试,其结果符合相应的期次划分类型。应用宏观构造、显微构造与组构分析,结合年代学测试综合分析,对于辽南变质核杂岩构造-岩浆活动性进行了精细划分,包括134~130Ma初始伸展阶段,130~115Ma峰期伸展与强烈岩浆活动阶段,以及115Ma前后伸展作用结束。     

辽南大莲花泡全新世地层中某些元素分布规律及古环境意义

在辽南大莲花泡全新世地层早、中、晚 3个沉积阶段中 Ca元素含量表现为低 -高 -低变化 ,Al,Mg,Cr,Ni,Cu,V,B,Mn等元素呈高 -低 -高分布。因子分析揭示出控制元素这种分布的主要因素是碎屑成因和生物成因。Ca元素的“稀释剂”作用改变了其他元素的实际含量 ,造成与干凉 -暖湿 -干凉的全新世气候变化不相匹配的假象。     

扬子区震旦纪地层序列和南、北方震旦系对比

198 2年“晚前寒武纪地层分类命名会议”决议“震旦系是青白口系之上的晚元古代最上部的一个年代地层单位 ,以三峡地区的剖面为代表 ,暂以莲沱组底界为底界”。但从区域性对比和同位素年代地层学分析 ,莲沱组底至黄陵花岗岩的侵蚀面之间有约 10 0 Ma的沉积缺失 ,莲沱组和南沱组也不能代表 75 0～ 6 6 0 Ma间的沉积历史。峡东地区震旦系下部地层不完整是显而易见的。本文赞同修订震旦系的含义 ,以下冰碛层 (古城组或铁丝坳组 )之底为震旦系的底界 ,年龄为 70 0 Ma。朝鲜飞浪洞组可与古城组、大塘坡组和南沱组对比 ,祥原系及辽南、徐淮地区的相当地层属“南华冰期”前的沉积地层。建议震旦系之下至青白口系顶 (85 0 Ma)之间建立辽南系 ,从而完善我国晚元古代年代地层框架     

辽南金州拆离带糜棱状花岗岩脉体变形特征及锆石SHRIMP U-Pb年龄——韧性拆离时限的新证据

辽南金州拆离断层带中发育糜棱状花岗岩脉。野外观察与显微构造分析显示该脉体为同构造变形脉体,与围岩太古宙片麻岩一起经历了伸展韧性剪切变形。长石Fry法的应变测量结果显示样品的付林参数K=0.83,罗德参数υ=0.09,应变强度Es=0.71,表明该岩石应变以平面应变为主,且有限应变较强;运动学涡度为Wk=0.89,表明剪切作用类型以简单剪切为主。对该花岗岩脉进行锆石SHRIMP U-Pb年代学测定,10颗岩浆锆石的206Pb/238U年龄加权平均值为129±2 Ma(MSWD=1.6),代表岩脉侵位年龄。结合该区研究的最新成果,表明金州拆离断层至少在129 Ma已经开始韧性变形,辽南地区构造体制在此时已经从缩短转折到伸展。     

The Liaonan metamorphic core complex, Southeastern Liaoning Province, North China: A likely contributor to Cretaceous rotation of Eastern Liaoning, Korea and contiguous areas

The Mesozoic Liaonan metamorphic core complex (mcc) of the southeastern Liaoning province, North China, is an asymmetric Cordilleran-style complex with a west-rooting master detachment fault, the Jinzhou fault. A thick sequence of lower plate, fault-related mylonitic and gneissic rocks derived from Archean and Early Cretaceous crystalline protoliths has been transported ESE-ward from mid-crustal depths. U–Pb ages of lower plate syntectonic plutons (ca. 130–120 Ma), ⁴⁰Ar–³⁹Ar cooling ages in the mylonitic and gneissic sequence (ca. 120–110 Ma), and a Cretaceous supradetachment basin attest to the Early Cretaceous age of this extensional complex. The recent discovery of the coeval and similarly west-rooting Waziyu mcc in western Liaoning [Darby, B.J., Davis, G.A., Zhang, X., Wu, F., Wilde, S., Yang, J., 2004. The newly discovered Waziyu metamorphic core complex, Yiwulushan, western Liaoning Province, North China. Earth Science Frontiers 11, 145–155] indicates that the Gulf of Liaoning, which lies between the two complexes, was the center of a region of major crustal extension.Clockwise crustal rotation of a large region including eastern Liaoning province and the Korean Peninsula with respect to a non-rotated North China block has been conclusively documented by paleomagnetic studies over the past decade. The timing of this rotation and the reasons for it are controversial. Lin et al. [Lin, W., Chen, Y., Faure, M., Wang, Q., 2003. Tectonic implication of new Late Cretaceous paleomagnetic constraints from Eastern Liaoning Peninsula, NE China. Journal of Geophysical Research 108 (B-6) (EPM 5-1 to 5-17)] proposed that a clockwise rotation of 22.5° ± 10.2° was largely post-Early Cretaceous in age, and was the consequence of extension within a crustal domain that tapers southwards towards the Bohai Sea (of which the Gulf of Liaoning is the northernmost part). Paleomagnetic studies of Early Cretaceous strata (ca 134–120 Ma) in the Yixian–Fuxin supradetachment basin of the Waziyu mcc indicate the non-rotation of North China and the basin [Zhu, R.X., Shao, J.A., Pan, Y.X., Shi, R.P., Shi, G.H., Li, D.M., 2002. Paleomagnetic data from Early Cretaceous volcanic rocks of West Liaoning: evidence for intracontinental rotation. Chinese Science Bulletin 47, 1832–1837]. Such upper-plate non-rotation supports our conclusion that the lower plates of the Waziyu and Liaonan metamorphic core complexes were displaced ESE-ward in an absolute sense away from the stable North China block, thus contributing to the rotation of Korea and contiguous areas. Rotation is inferred to have affected only the upper crust above mid-crustal levels into which we believe the Jinzhou and Waziyu detachment fault zones flattened. If this is the case, the regional Tan Lu fault that lies between the two core complexes was truncated at mid-crustal depth, since in areas to the south it forms the boundary between the North and South China lithospheric blocks. It is noteworthy that the two extensional complexes lie not far north of the Bohai Bay, the area proposed by Lin et al. [Lin, W., Chen, Y., Faure, M., Wang, Q., 2003. Tectonic implication of new Late Cretaceous paleomagnetic constraints from Eastern Liaoning Peninsula, NE China. Journal of Geophysical Research 108 (B-6) (EPM 5-1 to 5-17)] as the site of the pole of rotation for Korea's clockwise displacement.Lin et al. [Lin, W., Chen, Y., Faure, M., Wang, Q., 2003. Tectonic implication of new Late Cretaceous paleomagnetic constraints from Eastern Liaoning Peninsula, NE China. Journal of Geophysical Research 108 (B-6) (EPM 5-1 to 5-17)] were unaware of the Liaonan and Waziyu mcc's and argued that most of the regional block rotation was post-Early Cretaceous and, in part, early Cenozoic. However, the ca. 130–120 Ma ages of the two Liaoning mcc's and a Songliao basin mcc (Xujiaweizi), the latter discovered only by recent drilling through its younger stratigraphic cover, support our and some Korean coworkers' conclusions that most of the clockwise rotation was Early Cretaceous.     

辽南变质核杂岩主拆离断层的波瓦状构造(corrugation)及其成因

基于对辽南变质核杂岩主拆离断层及下伏韧性剪切带的几何学分析以及拆离断层带构造岩的显微构造研究,结合变质核杂岩构造—岩浆活动及其形成过程和力学机制,重点讨论了主拆离断层的波瓦状构造的特点及其形成条件。结果表明:波瓦状构造的发育与下盘晚期阶段花岗质岩体的侵位具有同时性。伸展构造发育初期就位的深成岩体加热和软化了上部地壳,此时岩石力学属性控制的钝角锯齿状断裂构成了波瓦状构造的雏形,晚期阶段花岗质深成侵入岩的不均匀侵位制约了波瓦状构造的发育。     

The Liaonan Metamorphic Core Complex： Constitution, Structure and Evolution

The Liaonan metamorphic core complex (mcc) has a three-layer structure and is constituted by five parts, i.e. a detachment fault zone, an allochthonous upper plate and an supradetachment basin above the fault zone, and highly metamorphosed rocks and intrusive rocks in the lower plate. The allochthonous upper plate is mainly of Neoproterozoic and Paleozoic rocks weakly deformed and metamorphosed in pre-Indosinan stage. Above these rocks is a small-scale supradetachment basin of Cretaceous sedimentary and volcanic rocks. The lower plate is dominated by Archean TTG gneisses with minor amount of supracrustal rocks. The Archean rocks are intruded by late Mesozoic synkinematic monzogranitic and granitic plutons. Different types of fault rocks, providing clues to the evolution of the detachment fault zone, are well-preserved in the fault zone, e.g. mylonitic gneiss, mylonites, brecciated mylonites, microbreccias and pseudotachylites. Lineations in lower plate granitic intrusions have consistent orientation that indicate uniform top-to-NW shearing along the main detachment fault zone. This also provides evidence for the synkinematic characteristics of the granitic plutons in the lower plate. Structural analysis of the different parts in the mcc and isotopic dating of plutonic rocks from the lower plate and mylonitic rocks from detachment fault zone suggest that exhumation of the mcc started with regional crustal extension due to crustal block rotation and tangential shearing. The extension triggered magma formation, upwelling and emplacement. This event ended with appearance of pseudotachylite and fault gauges formed at the uppermost crustal level. U-Pb dating of single zircon grains from granitic rocks in the lower plate gives an age of 130±5 Ma, and biotite grains from the mam detachment fault zone have 40Ar-39Ar ages of 108-119 Ma. Several aspects may provide constraints for the exhumation of the Liaonan mcc. These include regional extensional setting, cover/basement contact, temporal and spatial coupling of extension and magmatism, basin development and evolution of fault tectonites along detachment fault zone. We propose that the exhumation of the Liaonan mcc resulted from regional extension and thinning of crust or lithosphere in eastern North China, and accompanied with synkinematic intrusion of granitic plutons, formation of detachment fault zone, uplifting and exhumation of lower-plate rocks, and appearance of supradetachment basin.     

我国中新元古代地层研究中若干问题的探讨

以叠层石作为生物地层学研究的主要手段 ,并分析了一些新的同位素年龄和其他古生物学资料 ,对 3个中新元古代地层问题进行了讨论 :　 1)从元古宙叠层石总体发育过程及陡山沱组新发现的资料看 ,中国南方震旦系(指南沱 ,陡山沱和灯影组 )在层位上应位于胶辽徐淮区的金县群之上 ;　 2 )在震旦纪南沱冰期前 ,大约在辽南纪中晚期 ,一起高温氧化并伴随强蒸发事件波及胶辽徐淮区 ;　 3)对燕山 ,胶辽徐淮和扬子区中新元古代沉积的构造背景进行了分析。     

辽南地块新太古代2.52～2.46Ga构造-热事件的识别及地质意义

胶-辽-吉活动/造山带是华北克拉通早前寒武纪基底三条古元古代构造带之一,对其邻区内太古宙地质体的岩石组合和时空分布的研究,可为制约胶-辽-吉带的构造属性以及华北克拉通东部在古元古代时期的构造格局提供重要依据。胶-辽-吉带的北侧为龙岗地块,南侧为辽南和狼林地块,本文对辽南地块中典型前寒武纪基底变质岩石进行了详细的野外地质、岩石学和锆石LA-ICP-MS U-Pb年代学研究,结果显示原岩为石英闪长岩或英云闪长岩的黑云角闪片麻岩(DL05-1)和侵入其中的花岗质脉体(DL05-2)分别形成于2523±11Ma(MSWD=0.62)和2505±13Ma(MSWD=0.67),原岩为TTG岩系的黑云斜长片麻岩(DL10-1)形成于2521±12Ma(MSWD=1.15)。2件斜长角闪岩样品(DL12-1和DL07-1)分别给出2521±16Ma(MSWD=1.9)和2464±20Ma(MSWD=0.72)的~(207)Pb/~(206)Pb加权平均年龄,前者的锆石形态、结构和Th-U体系组成具有高温岩浆成因的特征,因此2521±16Ma代表基性原岩的形成时代,后者的锆石没有明显的内部结构,且Th、U含量低(分别为6×10~(-6)~29×10~(-6)、9×10~(-6)~26×10~(-6))具变质重结晶锆石的特征,2464±20Ma代表区域变质事件的年龄。侵入斜长角闪岩的2件花岗片麻岩样品(DL12-2和DL07-2)207Pb/206Pb加权平均年龄分别为2498±18Ma(MSWD=1.4)和2.1Ga,1件钾质花岗岩样品(DL17-1)由于强烈的Pb丢失未能获得准确的形成年龄,根据野外产状和锆石U-Th-Pb组成推测该钾质花岗岩形成于新太古代晚期。虽然辽南地块内太古宙表壳岩的时空分布规律目前还不清楚,但本文的研究结果进一步确认,辽南地块内存在新太古代2.52Ga基性岩、闪长岩和TTG组合,它们的形成时代总体上不晚于共生的花岗岩(2.50Ga),而后辽南地块经历了新太古代晚期2.46Ga区域变质作用的改造。侵位时代接近2.1Ga花岗岩的存在表明辽南地块太古宙陆壳在形成后受到2.1Ga构造-热事件的影响。另一方面,本文研究的花岗质岩石样品中残余锆石核年龄分布于2.61~2.51Ga,表明辽南地块内古老大陆地壳物质的形成时代至少可以追溯至新太古代早期。辽南地块内太古宙岩浆、变质作用时限和陆壳物质的形成时间都与华北克拉通东部可以对比,具有华北的太古宙基底属性。与狼林地块相比,辽南地块内太古宙的岩石类型更加丰富,规模也更大;与胶-辽-吉活动/造山带北侧龙岗地块相比,辽南地块内尚没有发现大规模条带状铁建造(BIF)和形成于新太古代之前(2.8Ga)的岩石,且变质程度相对较低。目前的地质和年代学证据尚不支持辽南地块与胶-辽-吉带北侧的龙岗地块原属于同一陆壳基底。