胶东莱西地区高压麻粒岩的Sm-Nd同位素年代学

在胶东地区莱西-莱阳-栖霞一带的晚太古代花岗片麻岩中,出露一条长约200多公里,NE向展布的高压基性麻粒岩-超镁铁质岩带。由于这条岩带东邻苏鲁高压-超高压变质带,西接华北克拉通基底的古老变质岩,因此其区域构造归属以及大地构造意义是一个十分重要的问题。本文分析的高压基性麻粒岩样品具有降压退变质结构,退变质矿物组合为麻粒岩相。矿物-全岩Sm-Nd等时线年龄为1752Ma,全岩T(DM)模式年龄为2788Ma,与华北克拉通北缘的高压基性麻粒岩的同位素年龄完全相似。根据高压麻粒岩-超镁铁质岩的围岩片麻岩特征和同位素年龄,可以确定这条出露于华北陆块东缘的岩带是早前寒武纪华北克拉通下地壳岩石,其抬升与华北陆块与扬子陆块的拼合有关。     

大别山北大别杂岩的大地构造属性

北大别杂岩主要由花岗质片麻岩及斜长角闪岩组成 ,含有不同类型、大小不等的麻粒岩岩块和变质超镁铁质岩块 ,侵入有大量白垩纪花岗岩和辉石 -辉长岩类。其中的花岗质片麻岩、斜长角闪岩具有岛弧环境的岩石地球化学特征 ,代表拼贴于扬子陆块北缘的新元古代古岛弧。北大别杂岩北可与庐镇关群相连 ,南俯于超高压变质岩之下 ,在三叠纪扬子陆块与华北陆块的碰撞过程中 ,曾与超高压变质岩一起俯冲到地幔深度并经受榴辉岩相变质作用 ,然后在折返过程中叠加了麻粒岩相及角闪岩相变质作用 ,是扬子陆块北缘陆壳俯冲基底的一部分     

北大别洪庙榴辉岩相岩石Sm-Nd年龄:峰期变质时代

前人工作认为北大别榴辉岩在榴辉岩相变质后,经历了麻粒岩相退变质作用,因此获得的Sm-Nd矿物等时线年龄代表了麻粒岩相变质时代.本文对北大别安徽洪庙百丈岩榴辉岩相岩石(辉石石榴石岩)的研究表明,该岩石经历了三叠纪超高压变质作用,经历了角闪岩相退变质.所研究样品在峰期变质之后是否经历了麻粒岩相退变质尚不能明确界定.结合矿物氧同位素体系平衡判据,辉石石榴石岩在峰期变质时达到了Sm-Nd同位素体系的均一化和平衡,并且在后期角闪岩相退变质中该同位素体系未出现明显的扰动,因此其Sm-Nd矿物等时线年龄[(225±14)Ma和(229±13)Ma]代表了榴辉岩相变质时代.同时,样品中矿物的同位素组成表明,在俯冲板块折返和退变质过程中,岩石受到外来和内部流体的不均匀作用,造成退变的单斜辉石在同位素组成上的不均一.     

康定杂岩成因和构造意义——来自Hf同位素的证据

康定杂岩位于扬子地块西缘,通过对四川康定—冕宁—攀枝花—云南元谋地区出露的康定杂岩中基性、中性、酸性岩岩石学、锆石Lu-Hf同位素等多方面系统研究,确定这套岩石形成于岛弧环境。分析表明:康定杂岩中镁铁质侵入体锆石εHf(t)变化范围-4.2~+11.0,Hf模式年龄742~2386 Ma;长英质侵入体锆石εHf(t)变化范围-4.9~+9.4,Hf模式年龄为967~2707 Ma;暗示康定杂岩体复杂的构造成因。锆石Hf同位素分析表明其岩浆锆石具有与扬子地块西缘同时代镁铁质/长英质侵入体相似的Hf同位素组成,暗示其相似的岩浆起源。研究表明,康定杂岩为大洋俯冲背景下的产物,镁铁质侵入体来源于较为亏损地幔源区,长英质侵入体为新生陆壳与古老地壳物质相互作用形成的产物。锆石Hf同位素数据表明,康定侵入体杂岩中锆石Hf-全岩Nd解耦,为"锆石效应"与少量地壳物质加入共同作用结果。结合岩石学、地层学、构造及地球化学证据综合表明,新元古代时期,扬子地块可能位于Gondwana超大陆的边缘,而不是澳大利亚与北美Laurentia古陆之间的连接部分。     

冀西北赤城太古代英云闪长质、花岗闪长质片麻岩的地球化学

作者通过对冀西北张家口-赤城地区广泛出露的所谓混合岩化黑云斜长片麻岩的地质、矿物、岩石和地球化学研究，确定了它们是太古代的英云闪长质、花岗闪长质片麻岩，并且认为它们不是变质的火山-沉积岩，而是地壳中先存的镁铁质角闪岩或麻粒岩的重熔岩浆在固结或半固结状态下被长英质麻粒岩部分熔融产生的熔浆混合、交代形成的产物。     

冀东三屯营地区片麻岩的早太古宙全岩年龄

冀东三屯营地区麻粒岩相片麻岩由三组中酸性岩石组成。三组片麻岩Pb-Pb全岩等时线年龄为。三组片麻岩也各给自出了早太古宙年龄。岩石的这一年龄,是麻粒岩相变质过程中U和Th亏损之后发生均匀化的结果,因而表明麻粒岩相的变质作用结束于3563Ma之前。岩石在3563～2500Ma期间处于角闪岩相的环境。文中还给出了全岩Rb-Sr同位素的年龄成果,为2500～2800Ma。     

大别山双河超高压变质矿物Ｏ同位素平衡及其对Sm-Nd和Rb-Sr等时线年龄有效性的制约

对大别造山带双河超高压榴辉岩和片麻岩Sm-Nd和Rb-Sr等时线矿物进行了O同位素地质测温。尽管Sm-Nd等时线给出一致的三叠纪年龄(213~238 Ma)，同一样品Rb-Sr等时线却给出侏罗纪年龄(171~174 Ma)。片麻岩、榴辉岩和榴闪岩矿物对O同位素测温得到600~720℃和420~550℃两组温度，分别对应于约225±5 Ma榴辉岩相变质和约175±5 Ma角闪岩相退变质条件下停止同位素扩散交换的温度。同一样品三叠纪Sm-Nd等时线年龄的保存、侏罗纪Rb-Sr等时线年龄的出现以及有规律的O同位素温度，表明在角闪岩相退变质过程中，Sr和O在含水矿物（如黑云母和角闪石）中的扩散速率在手标本尺度上比石榴石Nd和多硅白云母Sr的扩散速率快。     

青岛榴辉岩及胶南群片麻岩的锆石U-Pb 年龄——胶南群中晋宁期岩浆事件的证据

研究表明，苏鲁地体是扬子与华北陆-陆碰撞造山带的一部分（东段）。其主要变质岩系——胶南群，是扬子陆块北缘俯冲陆壳的基底。在已有的文献中，人们均将胶南群划为早、中元古代地体。组成胶南群的主要岩石是长英质片麻岩，在其中间包含有少量斜长角闪岩、大理岩、超镁铁岩和榴辉岩。大量的Sm-Nd 及 40Ar/39Ar 同位素定年已证明了，胶南群在三叠纪时，经历了与华北和扬子陆块碰撞有关的高压或超高压变质作用，原岩的时代缺乏可靠的年龄测定，被认为是早、中元古代岩石。然而最近我们对青岛附近仰口的退变质榴辉岩及胶南群片麻岩的     

山东沂水杂岩中变基性岩类的Sm—Nd同位素年龄及其地质意义

在山东太古宙沂水杂岩的变基性岩类中首次获得的Sm-Nd全岩等时线同位素年龄为2997Ma,证实了山东中部的郯庐断裂带中有中太古代麻粒岩相表壳岩存在。沂水杂岩的岩石组合主要有二辉斜长麻粒岩、二辉斜长片麻岩、二辉铁英岩(少量)、二辉斜长角闪岩和紫苏花岗岩类等,它们组成了山东最老的汞丹山地块,其时代大致相当于胶东群,但层位可能更为偏下。沂水杂岩为高角闪岩相至麻粒岩相。变基性岩的原岩相当低钾拉斑玄武岩,稀土配分具有较平坦型和轻稀土富集型两种模式。岩石的ε_(Nd)(t)值为+3.8±0.3,物源来自亏损(上)地幔。它与华北陆台北缘麻粒岩相中部分岩石的岩性十分相似,表明其源区的化学特征相似,但主体的稀土模式有所不同,说明太古宙不同地区相似岩石地球化学的不均匀性。     

辽西太古代建平变质杂岩的地球化学和变质作用的PTt轨迹

太古代建平变质杂岩主要由高Na/K比的、原岩为英云闪长岩-奥长花岗岩-花岗闪长岩系列(TTG)侵入岩的中性麻粒岩和片麻岩、少量变沉积岩、基性麻粒岩、斜长角闪岩和变超基性岩组成。各类岩石具有明显不同的地球化学特征。结合野外关系考虑,斜长角闪岩和基性麻粒岩可与世界其他高级区内的变质拉斑玄武岩对比;TTG片麻岩,中性麻粒岩、紫苏花岗岩和斜长质片麻岩可能由镁铁质源岩部分熔融而成。变质作用的演化轨迹为反时针型。因此,本区可与冀东、内蒙、南印度和苏格兰的刘易斯等高级地体对比。     

Rb-Sr and Sm-Nd Mineral Isochron Ages of the Metamorphic Rocks in the Namaqualand Metamorphic Complex, South Africa

Rb-Sr and Sm-Nd isotopic studies were carried out for metamorphic rocks in the Namaqualand Metamorphic Complex, South Africa. The metamorphic rocks give the Rb-Sr mineral isochron ages (whole-rock - biotite - felsic fractions) of 844±85 Ma and 811.6±6.6 Ma for the lower granulite zone and of 776.5±5.4 Ma for the upper granulite zone. The rocks yield the Sm-Nd mineral isochron ages of 1071±18 Ma (whole-rock - garnet - felsic fractions) and 1067±158 Ma (whole-rock - hornblende - biotite rich fraction - felsic fractions) for the lower granulite zone and of 1052.0±3.6 Ma and 1002.5±1.4 Ma (whole-rock - garnet - felsic fractions) for the upper granulite zone. These age data suggest that the granulite facies metamorphism took place at 1060-1000 Ma, and that the rocks cooled down at 850-780 Ma. The Sr and Nd isotopic compositions of metamorphic rocks are different between the lower and upper granulite zones.     

The Belomorian eclogite province: sequence of events and age of the igneous and metamorphic rocks of the Gridino association

Within the Belomorian eclogite province, near Gridino Village, rocks of different compositions (tonalite-trondhjemite-granodioritic gneisses, granites, mafic and ultramafic rocks) were metamorphosed. The metamorphism included subsidence with increasing pressure and temperature, an eclogite stage, decompression in the granulitic facies, and a retrograde stage in the amphibolitic facies. We attempted to characterize the succession and to date igneous and metamorphic events in the evolution of the Gridino eclogite association. For this purpose, we conducted the following studies: U–Pb isotope dating of zircon (conventional and SHRIMP II methods) from gneisses, a mafic dike, and a high-pressure granitic leucosome; U–Pb dating of rutile from mafic dikes; ⁴⁰Ar/³⁹Ar dating of amphibole and mica; and Sm–Nd studies of rocks and minerals. The Sm–Nd model ages of felsic (2.9–3.1 Ga) and mafic (3.0–3.4 Ga) rocks from the Gridino eclogite association and individual magmatic zircon grains with an age of ca. 3.0 Ga indicate the Mesoarchean age of the metamorphic-rock protoliths. The most reliable result is the upper age bound of eclogitic metamorphism (2.71 Ga), which reflects the time of the posteclogitic decompression melting of eclogitized rocks under high-pressure retrograde granulitic metamorphism. The mafic dikes formed from 2.82 Ga to 2.72 Ga, most probably, at 2.82 Ga, in accordance with the crystallization age of magmatic zircon from metagabbro. Superimposed amphibolitic metamorphism and the “final” exhumation of metamorphic complexes at 2.0–1.9 Ga are associated with the later Svecofennian tectonometamorphic stage. Successive cooling of the metamorphic associations to 300 °C at 1.9–1.7 Ga is shown by U–Pb rutile dating and ⁴⁰Ar/³⁹Ar mica dating.     

Origin of Mg-Metatholeiites of the Schirmacher Region,East Antarctica: Constraints from Trace Elements and Nd-Sr Isotopic Systematics

The mafic granulites of Schirmacher region, East Antarctica, the rocks under study, occur more or less as concordant sills or as lenses or as boudinage structures within the felsic rocks, charnockites or metapelites of the region. They show variation from garnet bearing two-pyroxene granulites and garnet free pyroxene granulites to transitional amphibolite-pyroxene granulites. Their major, trace, REE and isotopic chemistry are not distinct from each other and they represent Mg-basalts with MgO >7% and Al₂O₃ <16%.The majority of the analyzed samples plot in the tholeiitic field or show tholeiitic trends, suggesting their metatholeiitic nature as well as general preservation of original composition. The rocks are characterized by enriched large-ion lithophile elemental concentrations than that of mid-oceanic ridge basalts. Their high-field strength elements and heavy rare-earth elemental concentrations, however, are as that of mid-oceanic ridge basalts, a feature which is also reflected in the ratios of their large-ion lithophile elements against high-field strength elements and heavy rare-earth elements, wherein we find these ratios are higher than N-type MORB. Further, the rocks show negative Nb anomaly, high Th/Ta ratio and low La/Nb ratio, which are also characteristics of subduction-related magmatism.The isotopic studies carried out on these samples show that, the Sm-Nd and Rb-Sr dating did not yield much spread, but suggested a Sm-Nd metamorphic age of ∼960 Ma. Rb-Sr dating gave ages ∼886 Ma, suggesting the reworking of the Rb and Sr elements during subsequent tectonothermal overprinting. The Nd model ages (T_DM^Nd) of these rocks show a relatively restricted range of 1120 to 1357 Ma, suggesting mafic magmatism ∼1200 Ma. The positive eNd values (+4.22 to +6.07) shown by these rocks, represent a juvenile crustal fragment derived from melting of mantle precursors, without significant reworking of older crustal material. It is proposed that these rocks were produced by partial melting of a mantle source, characterized by LILE enrichment, related principally to dehydration of subducted oceanic crust.     

矿物之间的元素和同位素平衡:地质测温和等时线定年的热力学和动力学控制

在特定的地质事件过程中,矿物等时线放射体系是否达到并且保持了平衡是变质岩Sm-Nd和Rb-Sr同位素年代学中的一个重要问题。在这个问题上矿物对O同位素测温与矿物等时线定年相似,因此两者之间可以相互制约。在岩浆岩和变质岩中,矿物中Sm-Nd、Sr和O之间的扩散速率在无水的条件下一般具有可比性,因此矿物之间O同位素的平衡状态可以用来对Sm-Nd和Rb-Sr定年的有效性进行检验。对大别-苏鲁造山带超高压变质岩的Sm-Nd和Rb-Sr等时线矿物进行O同位素测温,得到Sm-Nd等时线有时给出三叠纪年龄,有时给出非三叠纪年龄;对应的矿物O同位素分馏分别处于平衡和不平衡状态。对于引起非三叠纪等时线年龄的原因,一方面可以是由于榴辉岩相变质过程中同位素体系没有达到平衡,另一方面则可能角闪岩相退变质作用打破了平衡。等时线矿物中初始同位素比值的均一化速率主要受慢扩散矿物的影响,而矿物等时线时钟的启动主要受高母/子比值矿物控制。因此在变质作用过程中,只有当高母/子比值矿物同时具有快的放射成因同位素扩散速率,才可能得到有效的矿物等时线来用于变质年龄的测定。根据不同矿物中不同元素在扩散速率上的差异,能够定量估计大陆碰撞过程中榴辉岩相变质的持续时间。应用增量方法和离子孔隙度经验模型,不仅分别能够从理论上准确计算所有固体矿物的氧同位素分馏系数和获得不同矿物中元素的扩散参数,而且分别能够定量预测热力学平衡条件下共生矿物之间的¹⁸O富集顺序和相同条件下矿物中元素扩散速率的相对快慢。     

太行山北段中生代岩基及其包体锆石U-Pb年代学和Hf同位素性质及其地质意义

太行山北段出露大规模中生代岩浆岩带,以中酸性岩为主,普遍含有基性微粒包体。锆石的SHRIMP U-Pb年代学研究表明,包体形成于126Ma左右,与寄主岩石大致同时形成。锆石的LA-MC-ICPMS Lu-Hf同位素原位测量研究表明,基性岩来自富集地幔的部分熔融,并遭受了一定程度的地壳混染;主要的中酸性岩基形成于壳幔岩浆混和过程,而岩基中微粒基性包体是经历分离结晶的基性岩浆注入酸性岩浆房中形成。     

Pan-African decompressional P-T path recorded by granulites from central Dronning Maud Land, Antarctica

A high-grade metamorphic complex is exposed in Filchnerfjella (6–8°E), central Dronning Maud Land. The metamorphic evolution of the complex has been recovered through a study of textural relationships, conventional geothermobarometry and pseudosection modelling. Relicts of an early, high-P assemblage are preserved within low-strain mafic pods. Subsequent granulite facies metamorphism resulted in formation of orthopyroxene in rocks of mafic, intermediate to felsic compositions, whereas spinel + quartz were part of the peak assemblage in pelitic gneisses. Peak conditions were attained at temperatures between 850–885 °C and 0.55–0.70 GPa. Reaction textures, including the replacement of amphibole and garnet by symplectites of orthopyroxene + plagioclase and partial replacement of garnet + sillimanite + spinel bearing assemblages by cordierite, indicate that the granulite facies metamorphism was accompanied and followed by decompression. The observed assemblages define a clock-wise P-T path including near-isothermal decompression. During decompression, localized melting led to formation of post-kinematic cordierite-melt assemblages, whereas mafic rocks contain melt patches with euhedral orthopyroxene. The granulite facies metamorphism, decompression and partial crustal melting occurred during the Cambrian Pan-African tectonothermal event.     

扬子块体南缘四堡群Sm－Nd同位素体系及其他壳演化意义

 详细的主元素和Sm-Nd同位素体系研究表明,扬子块体南缘元宝山地区四堡群中镁铁质-超镁铁质岩可能来源于Al亏损地幔;而宝坛地区镁铁质-超镁铁质岩的源区则可能包括了A1未亏损和A1亏损两种地幔端元组分,部分样品可能受到围岩混染。镁铁质-超镁铁质岩的Sm-Nd数据构成了一条无地质意义的假等时线,由其斜率获得的年龄约2.2Ga明显偏老。四堡群浅变质沉积岩的Nd模式年龄限定了镁铁质-超镁铁质岩和四堡群的地层年龄应小于1.8Ga.扬子南缘最老的基底四堡群(及相应地层)主要是由地壳存留年龄为1.8-1.9Ga的未成熟陆壳再循环物质组成,明显不同于华南块体(华夏古陆)的早-中元古代变质基底。迄今为止获得的沉积岩和花岗岩的Sm-Nd同位素资料都不支持扬子南缘存在早元古代-晚太古代基底。     

四川冕宁沙坝麻粒岩的岩石地球化学性质及形成时代

沙坝麻粒岩是扬子陆块西缘前寒武系变质杂岩的重要代表。麻粒岩具有Ba、Ce、LREE和Al的富集以及Nb、Ta、Zr、Hf、Ti和HREE亏损的岩石化学性质,结合对麻粒岩的Rb—Sr、Sm—Nd4、0Ar/39Ar和锆石U—Pb测年结果的分析和比较,表明沙坝麻粒岩的原岩形成于新元古代(780Ma)扬子陆块西缘活动大陆边缘的岛弧环境。根据对麻粒岩的变质演化历史和岩石地球化学特征分析,角闪岩相退变质的流体作用对麻粒岩的Rb—Sr、Sm—Nd和40Ar/39Ar同位素计时体系产生了严重干扰,这也是沙坝麻粒岩峰期变质和角闪岩相退变质时代难以确定的重要原因。     

胶北地体地壳演化：玲珑黑云母花岗岩继承锆石U-Pb年龄、微量元素和Hf同位素证据

胶北地体晚侏罗世下地壳重熔的玲珑黑云母花岗岩大面积出露,其中残留有大量继承锆石,记录了多期热事件,为复杂的地壳演化过程提供了重要线索。论文通过分析玲珑黑云母花岗岩中继承锆石的U-Pb年龄、微量元素和Hf同位素组成,探讨了胶北地体的地壳演化历史。结果显示胶北地体前寒武纪经历了~2.9Ga和~2.7Ga两期主要的地壳生长事件,~2.5Ga和2.2~1.8Ga两期地壳重熔改造事件,~2.5Ga和1.95~1.8Ga两期变质事件。~2.9Ga的岩浆作用形成于岛弧环境,~2.7Ga岩浆活动与下地壳基性物质的部分熔融有关,~2.5Ga发生的岩浆和变质事件与地幔柱底侵作用有关,并有同时期的表壳岩组合-胶东岩群形成。~2.1Ga地壳处于拉张状态,伴有与裂谷活动有关的双峰式岩浆作用,荆山群和粉子山群开始沉积,而后1.95~1.8Ga发生碰撞造山运动,胶北所有早前寒武纪岩石单元卷入此次事件,并发生变质作用。自此之后,直至二叠纪末,胶北处于岩浆活动的沉寂期,但于~1.7Ga和~1.0Ga发生沉积作用,形成芝罘群和蓬莱群。二叠纪末扬子板块向北俯冲于华北克拉通之下,并于三叠纪与华北克拉通发生陆陆碰撞作用,致使扬子板块北缘新元古代花岗岩发生超高压变质,形成苏鲁超高压变质带,之后超高压变质岩发生折返。玲珑黑云母花岗岩复杂的继承锆石组成可能表征了前寒武纪岩石卷入陆-陆碰撞事件而发生再循环作用。     

What Happened in the Trans-North China Orogen in the Period 2560-1850 Ma？

The Trans-North China Orogen （TNCO） was a Paleoproterozic continent-continent collisional belt along which the Eastern and Western Blocks amalgamated to form a coherent North China Craton （NCC）. Recent geological, structural, geochemical and isotopic data show that the orogen was a continental margin or Japan-type arc along the western margin of the Eastern Block, which was separated from the Western Block by an old ocean, with eastward-directed subduction of the oceanic lithosphere beneath the western margin of the Eastern Block. At 2550-2520 Ma, the deep subduction caused partial melting of the medium-lower crust, producing copious granitoid magma that was intruded into the upper levels of the crust to form granitoid plutons in the low- to medium-grade granite-greeustone terranes. At 2530-2520 Ma, subduction of the oceanic lithosphere caused partial melting of the mantle wedge, which led to underplating of mafic magma in the lower crust and widespread mafic and minor felsic volcanism in the arc, forming part of the greenstone assemblages. Extension driven by widespread mafic to felsic volcanism led to the development of back-arc and/or intra-arc basins in the orogen. At 2520-2475 Ma, the subduction caused further partial melting of the lower crust to form large amounts of tonalitic-trondhjemitic-granodioritic （TTG） magmatism. At this time following further extension of back-arc basins, episodic granitoid magmatism occurred, resulting in the emplacement of 2360 Ma, -2250 Ma 2110-21760 Ma and -2050 Ma granites in the orogen. Contemporary volcano-sedimentary rocks developed in the back-arc or intra-are basins. At 2150-1920 Ma, the orogen underwent several extensional events, possibly due to subduction of an oceanic ridge, leading to emplacement of mafic dykes that were subsequently metamorphosed to amphibolites and medium- to high-pressure mafic granulites. At 1880-1820 Ma, the ocean between the Eastern and Western Blocks was completely consumed by subduction, and the dosing of the ocean led to the continent-arc-continent collision, which caused large-scale thrusting and isoclinal folds and transported some of the rocks into the lower crustal levels or upper mantle to form granulites or eclogites. Peak metamorphism was followed by exhumation/uplift, resulting in widespread development of asymmetric folds and symplectic textures in the rocks.