肥东杂岩的锆石U-Pb年龄及其地质意义——兼论下扬子地区新元古代岩浆活动历史

近年来在下扬子西缘地区厘定的一系列新元古代火成岩,为认识该区扬子板块新元古代岩浆活动历史与规律提供了窗口。结合本次与前人锆石U-Pb年代学数据,指示下扬子地区张八岭群、肥东杂岩与董岭杂岩内变火成岩的原岩时限分别为767~748 Ma、812~745 Ma和829~754 Ma。这些新元古代火成岩分别是峰期为750 Ma、800 Ma和825 Ma岩浆活动的产物。下扬子地区峰期为825 Ma的岩浆活动只出现在靠近江南造山带的南部。锆石年代学信息显示,下扬子地区还发生过峰期为840 Ma、2010 Ma和2454 Ma岩浆活动,但缺失1000~860 Ma的岩浆活动。通过区域对比表明,攀西—汉南弧没有延入下扬子地区。下扬子地区南部受到峰期为840 Ma的弧岩浆活动的影响。扬子板块上峰期为825 Ma的岩浆活动及早阶段的南华裂谷应是江南造山带后造山伸展的产物;而峰期为800 Ma和750 Ma的岩浆活动与相应的南华裂谷扩展,代表了Rodinia超大陆裂解的全面影响。     

塔里木溢流玄武岩火山通道的三维结构及其热成因气体释放

塔里木上奥陶统-志留系沉积地层中广泛发育早二叠世溢流玄武岩的火山通道相岩床-岩墙网络。三维地震数据解释结果显示,这些火山通道以平行围岩地层的岩床和斜切围岩地层的"碟状岩床"为主要特征。在玄武岩喷发过程中,火山通道岩浆的热量可以导致沉积围岩发生热接触变质并将沉积围岩中的有机质转化为"热成因气体"。在塔北英买2井区火山通道烘烤沉积围岩模型基础上,利用有限元热模拟方法确定了该区早二叠世玄武岩喷发时火山通道热烘烤影响范围随时间的变化。基于沉积围岩有机质丰度估算,该区热烘烤成因甲烷释放量可达11.3Gt(即113亿吨)。如果整个塔里木溢流玄武岩省具有与英买2地区相同的释放强度,则塔里木溢流玄武岩省活动期间释放的甲烷总量可达7062.5Gt,必然导致非常显著的环境效应。同时,玄武岩火山通道岩浆引起的热接触变质作用对已存在的油藏具有明显的破坏作用,塔里木盆地古生界总量约8~10Gt的油藏破坏和大量沥青的形成可能与此有关。     

滇西澜沧岩群碎屑锆石U-Pb定年及其地质意义

虽然前人对澜沧岩群做了大量的研究,但缺乏同位素年代学方面的研究。此次研究针对澜沧江南段菖蒲塘-大田山地区澜沧岩群绢白云母石英片岩进行碎屑锆石U-Pb定年,为澜沧岩群的形成时代增添年代学证据。极大多数(129粒)锆石阴极发光(CL)图像显示其有明显的结晶振荡环带,指示其为岩浆成因的碎屑锆石,129粒碎屑锆石具有多组峰值年龄,最年轻一组年龄加权平均值为452±26Ma,表明澜沧岩群最早沉积时限不早于452±26Ma;极少数(1粒)锆石具弱阴极发光,缺乏内部结构特点,认为其为变质重结晶锆石,变质结晶锆石U-Pb年龄为255±3Ma,与前人研究所得澜沧岩群变质时代基本吻合。综合分析,澜沧岩群的沉积时限不早于452±26Ma,在二叠纪末期可能发生变质作用。     

滇中地区因民角砾岩类型、特征及找矿意义

滇中地区“因民角砾岩”的成因及归属问题目前暂无定论。笔者通过对东川-易门地区前人所划的因民组“因民角砾岩”进行1：5万野外地质调查工作,对其进行了初步的分类。根据其成因及时代划分为复成分砾岩、冰碛砾岩、滑塌角砾岩、引爆角砾岩和构造角砾岩。对“因民角砾岩”成因及时代的研究,特别是“冰碛砾岩、复成分砾岩”的提出,对于解决滇中早前寒武纪地层层序、时代归属、构造格架、大地构造位置及大区域地层对比,探讨滇中元古宙地史演化、古环境研究以及指导找矿都具有重要的指示意义。     

青岛连三岛地区“荆山岩群”高压变质岩的变质时代和变质演化特征

青岛连三岛地区原划为古元古界荆山岩群中出露各类片岩、片麻岩。本文在前人研究的基础上,对连三岛地区出露的含榴黑云母斜长片麻岩、含榴云母片岩和含榴黑云母钾长片麻岩,进行详细的岩相学和矿物化学研究,确定其变质温压条件及其P-T演化轨迹,并采用LA-ICP-MS锆石U-Pb定年,获得了3个样品的原岩时代和变质时代,为全面深入认识其变质属性提供了进一步的重要依据。根据岩相学和矿物化学成分可以识别出两期矿物组合:第一期(峰期变质阶段)为Grt1+Kfs+Aln+Ph+Qtz;第二期(退变质阶段)为Grt2+Pl+Ep+Bt+Qtz;依据多硅白云母Si压力计、锆石Ti温度计以及GB-GBPQ矿物温压计,确定其峰期变质和退变质的温压条件分别为T=600～817℃、P=2.4～2.6GPa和T=431～456℃、P=0.48～0.82GPa。结合白云母部分熔融现象,上述两个变质阶段构成了一个折返早期升温降压,后穿过多硅白云母熔融反应线,最后降温降压的顺时针型演化的P-T轨迹。CL图像显示3个样品的锆石均具有典型的岩浆核-变质边结构;结合LA-ICP-MS锆石原位微区U-Pb定年和微量元素分析,3个样品分别获得了769～756Ma、～223Ma和213～216Ma三组年龄,分别与苏鲁造山带其他高压-超高压变质岩的新元古代原岩时代(700～800Ma)、峰期变质时代(240～225Ma)和角闪岩相退变质时代(215～205Ma)一致。对样品含榴黑云母斜长片麻岩(17LSD-1)和含榴云母片岩(18LSD-2)进行锆石Hf同位素分析,获得样品17LSD-1的ε_(Hf)(t)=-23.2～2.8、t_(DM2)~C(Hf)=1712～2845Ma,表明其原岩主要来源于古元古代陆壳重熔;样品18LSD-2的ε_(Hf)(t)=-13.9～8.6、t_(DM2)~C(Hf)=1113～2358Ma,表明样品形成时壳源物质成分占主导地位,同时部分幔源或新生地壳物质的加入,导致少部分ε_(Hf)(t)偏正值。Hf同位素结果表明连三岛变质岩原岩的形成与扬子板块新太古代-早古元古代的陆壳重熔有关。对比前人的相关数据,无论是原岩时代、变质年龄还是变质演化特征,本文研究的连三岛地区片岩/片麻岩与苏鲁造山带的部分变质岩均具有相似的原岩属性和变质属性,因此推断其应归属为苏鲁超高压变质带的一部分,是三叠纪扬子板块向华北板块俯冲碰撞引发的高压-超高压变质事件的产物,不应再作为岩石地层单元划归为"荆山岩群"。     

长乐-东山构造-岩浆带中北段地质特征

从复杂的构造变形中甄别出岩浆岩的塑性流动变形,与韧性和脆-韧性变形区别,力争还原长乐—泉州沿海一带地质构造的真实面目,并探讨了该带的活动时间和构造属性。另外还对该带长期争论的澳角群进行了初步的分解,锆石SHRIMP测年数据也反映了平潭南务里一带变质岩的复杂性。     

上扬子区寒武系娄山关群白云岩层序地层格架及其古地理背景

上扬子区特别是贵州及其邻区的寒武系娄山关群发育一套化石贫乏的浅水台地相白云岩,横跨中、上寒武统,厚度上千米,自北西向南东随着沉积环境水体的加深逐渐相变为开阔海台地相灰岩、陆棚相泥页岩等。由于化石贫乏难以进行详尽的年代地层划分,但是发育石盐假晶泥晶白云岩所反映的沉积环境水体变浅以及发育颗粒白云岩所反映的水体加深,表明可以应用从岩相序列到沉积相序列的方法对该套白云岩进行层序地层划分,成为在“海平面变化的框架内探讨沉积相迁移”的典型代表。巨厚的贫乏化石的娄山关群白云岩与下伏厚度较小、产三叶虫化石的陡坡寺组白云质细粒混合岩系形成了鲜明的对照,它们组成了1个二级层序,并可以划分为7个三级层序。陡坡寺组细粒混合岩系代表了二级海侵作用所造成的水体加深,而娄山关群白云岩自北西向南东进积尖灭则代表了二级海退过程所造成的水体变浅。该二级层序本身即是1个总体向上变浅的沉积相序列,其相序组构与三级层序相似,三级层序的相序组构与那些由岩相序列所组成的若干环潮坪型米级旋回也具有相似性。因此研究区娄山关群白云岩构成了1个复杂而有规律的、独特的层序地层格架,并由此反映了沉积物的时间演变序列和沉积相的空间展布特征具有一定的规律性,代表了其古地理演变过程既受制于海侵加深和海退变浅的时间过程,同时又受控于沉积环境水体自北西向南东由浅变深的空间变化过程。娄山关群白云岩的层序地层研究表明：层序地层学研究的核心是沉积物的时间演变序列以及沉积相的空间展布形式所代表的规律性,并根据这种规律性进行地层划分和对比。     

Tortonian-Pleistocenic oceanic features in the Southern Tyrrhenian Sea: magnetic inverse model of the Selli-Vavilov region

We show the magnetic model of the Selli-Vavilov region. The Selli Line is known as the northwestern edge of the southern Tyrrhenian Basin. The tectonic evolution of the Tyrrhenian Basin is dominated by a Tortonian-Quaternary extension through the eastward movement of the Apennine subduction system. This migration has generated a diffuse stretching of the continental crust with the emplacement of new oceanic material. This latter occurred in several localized zones where the eastward retreating of the Ionian subduction system produced a strong depletion of the crust with formation of basins and correlated spreading. Nowadays the presence of oceanic crust is confirmed through direct drilling investigation but a complete mapping of the oceanic crustal distribution is still lacking. The Selli-Vavilov region shows a differentiated crustal setting where seamount structures, the oceanic basement portions and continental crust blocks are superimposed. To this aim, a 2D inversion of the magnetic data of this region was conducted to define buried structures. The magnetic susceptibility pattern was computed by solving the least squares problem of the misfit between the predicted and real data for separated wavebands. This method produced two 2D models of the high and low frequency fields of the Selli-Vavilov region. The two apparent susceptibility maps provide different information for distinct ranges of depth. The results of the inversions were also combined with seismic data of the Selli region highlighting the position of the highly magnetized buried bodies. The results confirm a role for the Selli Line as a deep crustal boundary dividing the Sardinian passive domain from the easternmost active region where different oceanic structures are located. The Selli Line has worked as a detachment fault system which has moved eastward. Finally, the Selli-Vavilov region may be interpreted as a tectonic result due to a passive asymmetrical rift occurred between the Tortonian and Pliocene.     

A new understanding of Demala Group complex in Chayu Area,southeastern Qinghai-Tibet Plateau: Evidence from zircon U-Pb and mica 40Ar/39Ar dating

The Chayu area is located at the southeastern margin of the Qinghai-Tibet Plateau. This region was considered to be in the southeastward extension of the Lhasa Block, bounded by Nujiang suture zone in the north and Yarlung Zangbo suture zone in the south. The Demala Group complex, a set of high-grade metamorphic gneisses widely distributed in the Chayu area, is known as the Precambrian metamorphic basement of the Lhasa Block in the area. According to field-based investigations and microstructure analysis, the Demala Group complex is considered to mainly consist of banded biotite plagiogneisses, biotite quartzofeldspathic gneiss, granitic gneiss, amphibolite, mica schist, and quartz schist, with many leucogranite veins. The zircon U-Pb ages of two granitic gneiss samples are 205 ± 1 Ma and 218 ± 1 Ma, respectively, representing the ages of their protoliths. The zircons from two biotite plagiogneisses samples show core-rim structures. The U-Pb ages of the cores are mainly 644 –446 Ma, 1213 –865 Ma, and 1780 –1400 Ma, reflecting the age characteristics of clastic zircons during sedimentation of the original rocks. The U-Pb ages of the rims are from 203 ± 2 Ma to 190 ± 1 Ma, which represent the age of metamorphism. The zircon U-Pb ages of one sample taken from the leucogranite veins that cut through granitic gneiss foliation range from 24 Ma to 22 Ma, interpreted as the age of the anatexis in the Demala Group complex. Biotite and muscovite separates were selected from the granitic gneiss, banded gneiss, and leucogranite veins for ⁴⁰Ar/³⁹Ar dating. The plateau ages of three muscovite samples are 16.56 ± 0.21 Ma, 16.90 ± 0.21 Ma, and 23.40 ± 0.31 Ma, and the plateau ages of four biotite samples are 16.70 ± 0.24 Ma, 16.14 ± 0.19 Ma, 15.88 ± 0.20 Ma, and 14.39 ± 0.20 Ma. The mica Ar-Ar ages can reveal the exhumation and cooling history of the Demala Group complex. Combined with the previous research results of the Demala Group complex, the authors refer that the Demala Group complex should be a set of metamorphic complex. The complex includes not only Precambrian basement metamorphic rock series, but also Paleozoic sedimentary rock and Mesozoic granitic rock. Based on the deformation characteristics, the authors concluded that two stages of the metamorphism and deformation can be revealed in the Demala Group complex since the Mesozoic, namely Late Triassic-Early Jurassic (203 –190 Ma) and Oligocene –Miocene (24 –14 Ma). The early stage of metamorphism (ranging from 203 –190 Ma) was related to the Late Triassic tectono-magmatism in the area. The anatexis and uplifting-exhumation of the later stage (24 –14 Ma) were related to the shearing of the Jiali strike-slip fault zone. The Miocene structures are response to the large-scale southeastward escape of crustal materials and block rotation in Southeast Tibet after India-Eurasia collision.©2021 China Geology Editorial Office.