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。     

大别山高级变质岩云母Rb—Sr等时线年龄测定及其地质意义

应用云母Rb Sr等时线法对大别山高级变质岩的后期改造历史进行了初步的探讨。采用重液变温技术将云母按比重的区别 ,分成若干组分 ,然后用常规的Rb Sr方法测定。应用这种技术对大别山黄土岭太古代麻粒岩相岩石中的黑云母和产于超高压变质带内的石马含石榴石片麻岩的白云母进行了Rb Sr等时线年龄测定。黄土岭太古代麻粒岩相片麻岩中的黑云母 全岩Rb Sr等时线年龄为 12 7± 9Ma ,与该区片麻岩中的角闪石的K Ar和Ar Ar年龄 ,及燕山期花岗岩的Rb Sr年龄一致 ,说明这一太古代下地壳岩石受到了燕山期深熔 岩浆事件的影响 ;大别山东南部石马含石榴石片麻岩 (榴辉岩相 )中的白云母Rb Sr等时线年龄为 191± 10Ma ,反映了印支 早燕山期区域性低级变质事件的时代。研究表明 ,大别山区的不同构造单元中产出的不同类型的高级变质岩自中生代以来有不同的后期演化历史。     

柴达木盆地南缘金水口群的早古生代构造热事件:锆石U-Pb SHRIMP年龄证据

通过柴达木盆地南缘(东昆仑北缘)原定为金水口群麻粒岩相片麻岩和花岗质岩石中锆石的SHRIMP测定,确定其麻粒岩相变质时代为460Ma±8Ma,而具有深熔成因特征的花岗质岩石深熔作用时间为402Ma±6Ma。这些年龄数据表明,金水口群经历了早古生代与麻粒岩相变质和深熔作用有关的构造热事件,原认为是柴达木地块的前寒武纪变质基底明显在早古生代造山过程中发生了活化作用。花岗质岩石的继承锆石给出了少量太古宙和大量1600～1800Ma之间的年龄,代表了其锆石的主要源区物质年龄,这与祁连—柴达木地区以及扬子地块的地壳形成年龄基本一致,反映柴南缘(东昆仑北缘)的变质基底与扬子克拉通具有明显的亲缘性。     

山东半岛荆山群富铝片麻岩锆石U-Pb定年及其地质意义

荆山群富铝片麻岩广泛分布于山东半岛早前寒武纪变质基底之中。锆石阴极发光图像分析和U-Pb定年结果表明,荆山群富铝片麻岩中锆石成因比较复杂,可划分为3种类型:第一类为继承性(岩浆或碎屑)锆石,U-Pb定年结果显示该类锆石微区记录了~2 650 Ma和~2 100 Ma两组207Pb/206Pb年龄,这不仅表明研究区变质基底在中太古代末期和古元古代早期至少存在两期岩浆-热事件,同时,也说明荆山群原岩形成时代应晚于2 100 Ma;第二类为变质锆石,记录的207Pb/206Pb年龄集中在1 900~1 850 Ma之间,应代表荆山群富铝片麻岩峰期高压麻粒岩相变质时代;第三类亦为变质锆石,记录的207Pb/206Pb年龄集中在1 840~1 820 Ma之间,应代表荆山群富铝片麻岩峰后中低压麻粒岩相退变质时代。该项成果准确地限定了荆山群富铝片麻岩的原岩形成时代、峰期高压麻粒岩相变质时代和峰后中低压麻粒岩相退变质时代的年代学格架,对深入探讨华北克拉通东南缘高压麻粒岩的成因机制及其形成的动力学背景具有重要的科学意义。     

胶北早前寒武纪变质基底多期岩浆-变质热事件:来自TTG片麻岩和花岗质片麻岩中锆石U-Pb定年的证据

本文采用LA-ICP-MS技术,对胶北地体TTG片麻岩和花岗质片麻岩中锆石进行系统原位U-Pb定年和稀土、微量元素的分析,发现研究区早前寒武变质结晶基底存在多期岩浆-变质热事件。4件TTG片麻岩和2件花岗质片麻岩锆石样品记录了2909±13Ma、2738±23Ma、2544±15~2564±12Ma和2095±12Ma 4组岩浆事件年龄,以及2504±16~2513±32Ma和1863±41Ma 2组变质事件年龄。结合以往TTG片麻岩和花岗质片麻岩的地球化学及Nd同位素研究发现,约2738Ma的TTG岩浆事件可能代表胶北地体地壳最主要的生长事件,而2544~2564Ma的岩浆事件则可能代表古老地壳重熔的最强烈岩浆事件,约2095Ma岩浆事件则反映了胶-辽-吉构造带内部在该时期与地壳拉张作用有关的岩浆活动。2504~2513Ma是研究区以及华北克拉通早前寒武基底最主要的一期变质热事件,可能与地幔柱(热点)岩浆的底侵作用有关,而TTG片麻岩记录的约1863Ma的变质年龄与研究区基性和泥质高压麻粒岩相岩石记录的麻粒岩相变质时代一致,暗示TTG片麻岩可能也经历了古元古代高压麻粒岩相变质作用,上述研究进一步表明胶北地体在古元古代的确存在一期陆-陆碰撞的重要造山事件。该项研究成果对于进一步深入探讨胶北乃至华北克拉通早前寒武纪变质基底的形成演化、岩浆-变质热事件序列及其构造背景具有重要的科学意义。     

桐柏秦岭岩群的两类变质作用

本文重点对河南桐柏地区的秦岭岩群进行了观察与研究,根据野外地质、岩相关系及同位素测年资料,提出该区秦岭岩群具有明显不同的两类变质作用,一是较早期的高温麻粒岩相变质作用,以包体或长透镜群、甚至巨型条块状局限于中部郭庄组的花岗质片麻岩之中。根据伟晶岩、片麻岩及麻粒岩锆石年龄的综合限定,该变质作用的时间可能为~498Ma,多数人主张的445~430Ma的麻粒岩相变质年龄实际上是早期锆石被后期岩浆或变质事件引起的同位素体系重启年龄。另一种是相对晚期的角闪岩相变质作用,变质程度以角闪岩相为主,局部达高角闪岩相,没有任何早期高温或高压变质的残留迹象,形成秦岭岩群中主导类型的变质作用。同样,采用伟晶岩及有关片麻岩和麻粒岩中锆石测年限定,角闪岩相变质时间可能为~472Ma。高温麻粒岩的产出具有其特殊机制,大量的花岗质岩浆侵位过程中把地壳深部的高温麻粒岩裹挟上升至浅部层次,随后一起遭受区域上的角闪岩相变质作用。     

北秦岭造山带的早古生代多期变质作用

北秦岭造山带的秦岭岩群以高级变质岩石为特征,主要包括少量榴辉岩、高压麻粒岩和区域上广泛分布的麻粒岩-角闪岩相变质岩石。年代学研究显示秦岭岩群中不同岩石记录了多期变质作用。已有的定年资料给出北秦岭官坡地区的榴辉岩的年龄为500Ma左右,代表榴辉岩相的变质时代。结合岩相学资料,对两个高压麻粒岩样品的SHRIMP和LA-ICPMS U-Pb测定分别获得504±7Ma 和506±3Ma的年龄,应代表高压麻粒岩相变质时代。这表明高压麻粒岩和相邻的榴辉岩有相近的变质时代,但形成在造山带中不同的构热造环境中。西峡地区的角闪二辉麻粒岩的U-Pb定年给出两组早古生代年龄,一组为440±2Ma,可能代表了中低压麻粒岩相的变质时代,另一组为426±1Ma,应代表区域角闪岩相的变质时代。桐柏山北部的石榴二辉麻粒岩的U-Pb定年数据给出436±1Ma的年龄,为中压麻粒岩相的变质时代。这些资料表明北秦岭造山带经历了早奥陶世的俯冲和地壳增厚作用,并在晚志留世遭受了广泛的巴罗式区域变质作用。     

滇西南那邦变质基性岩两期变质作用的40Ar/39Ar年代学研究

中缅边界那邦变质基性岩出露于东缅著名的 Mogok带的东缘。那邦基性麻粒岩经历了早期麻粒岩相、晚期角闪岩相的两期变质作用的改造。早期变质作用的矿物石榴石和单斜辉石的 40 Ar/ 39Ar激光微区等时线年龄是 74.44± 1.44 Ma;石榴石和单斜辉石的 40 Ar/ 39Ar年龄谱图和等时线年龄均显示两组年龄 :74～ 76 Ma和 2 3～ 2 4Ma。晚期变质作用矿物角闪石的K- Ar法得出 2 3Ma,角闪石和斜长石的 40 Ar/ 39Ar年龄谱图和等时线年龄均显示 2 3～ 2 4Ma的变质年龄。综合这些结果 ,可以确定那邦基性麻粒岩的早期麻粒岩相变质作用的年龄是 74～ 77Ma,可能与新特提斯洋壳俯冲事件有关 ;晚期角闪岩相变质作用的年龄是 2 3～ 2 4Ma,与区内喜山期以来陆内块体响应两大陆会聚作用发生的大型走滑事件有关。那邦基性麻粒岩是世界上最年轻的麻粒岩相岩石之一 ,而且 ,两期变质作用年龄的确定对揭示区内与变质作用相关的地质事件具有重要意义。     

华北克拉通孔兹岩带中段大青山-乌拉山变质杂岩立甲子基性麻粒岩年代学及地球化学研究

大青山-乌拉山变质杂岩立甲子基性麻粒岩主要由角闪二辉麻粒岩、含榴角闪二辉麻粒岩和黑云角闪二辉麻粒岩所组成,并以变形岩墙和不规则透镜体形式赋存于富铝片麻岩和花岗质片麻岩之中.立甲子基性麻粒岩中变质锆石含有单斜辉石(Cpx)+角闪石(Amp)+斜长石(Pl)+磷灰石(Ap)的包体矿物,与寄主岩石——基性麻粒岩矿物组合及其化学成分十分一致,相应的207 pb/206 Pb表面年龄变化于1933±39Ma ～ 1834±40Ma,加权平均年龄为1892±7Ma(MSWD =0.50,n=46),应代表立甲子基性麻粒岩原岩经历中低压麻粒岩相的变质时代.在变质过程中,以大离子亲石元素(K、Na、Sr、Rb)为代表的活动元素发生了显著的改变;而高场强元素(Nb、Zr、Ti)和稀土元素基本无变化,保持稳定.立甲子基性麻粒岩原岩属于拉斑玄武质岩石系列,其SiO2集中变化于45.58％ ～51.40％,Mg#值集中介于41 ～54之间;在球粒陨石标准化稀土配分图中,立甲子基性麻粒岩具有平坦型的稀土配分曲线特征((La/Yb)cN=1.30～1.51),Eu异常不明显(Eu/Eu*=0.93～1.04).与显生宙岛孤拉斑玄武岩类似,立甲子基性麻粒岩所有样品皆具有Nb、Zr、Ti负异常特征.综合分析认为,立甲子基性麻粒岩原岩形成于2450～1930Ma,并于～1900Ma经历中低压麻粒岩相变质作用的改造,其主量元素和微量元素组成具有岛弧拉斑玄武质岩石的地球化学特征,其原岩可能是板块汇聚动力学背景下,岛弧构造环境中形成的辉长岩或辉绿岩.     

大别山北部榴辉岩和英云闪长质片麻岩锆石U-Pb年龄及多期变质增生

大别山北部榴辉岩及英云闪长质片麻岩的锆石U-Pb年龄分析表明：北部榴辉岩相峰期变质时代为226～230Ma左右;北部塔儿河一带英云闪长质片麻岩经历过印支期变质事件;大别山北部与南部超高压岩石中一致的（226～230Ma）高压或超高压变质年龄表明,北部镁铁-超镁铁质岩带中部分岩石也曾作为扬子俯冲陆壳的一部分,在印支期发生过高压或超高压变质作用;本区锆石发生过两期变质增生事件,一是印支期高压或超高压变质,另一期是燕山期热变质事件;榴辉岩及英云闪长质片麻岩的原岩形成时代为晚元古代;锆石U-Pb年龄可用多期变质增生模型来解释。     

冀东迁西三屯营地区早太古宙三组片麻岩的岩石地球化学及其成因

冀东迁西三屯营地区的高级变质杂岩,主要由早太古宙的三组片麻岩所组成。岩石地球化学研究表明,较早期的三屯营片麻岩为钙碱性石英闪长质岩石,除U和Th外,它不亏损不相容元素。较晚期的小关庄片麻岩和秋花峪片麻岩,分别为钙碱性石英闪长质和钙碱性英云闪长—奥长花岗质岩石,二者均发生了不相容元素的亏损。三屯营地区的岩石亏损与未亏损是源岩浆所具有的特征,可能是初始地壳形成时上地幔不均匀造成的。     

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.     

苏鲁造山带东北端石榴辉石麻粒岩的Sm-Nd同位素年代学及其大地构造含义

大量含石榴石的基性麻粒岩透镜体出露于苏鲁变质带的北部及邻近地区,它们可能是再变质的高压变质岩石。在详细的岩相学研究的基础上,确定采自莱西和文登的样品WD01、WD04、ML06 是由高压麻粒岩经中-高压麻粒岩相再变质形成的,而采自威海的样品WH1 是由柯石英榴辉岩经中-高压麻粒岩相再变质形成的。Sm-Nd 同位素年代学研究也证实了二者的重大差别。3 个高压麻粒岩样品的矿物-全岩内部等时线年龄分别是1 846+ /-76Ma,1 743+ /-79Ma 和1 752+ /-30Ma,TDM 模式年龄是3.3Ga,3.0Ga 和2.8Ga.上述数据说明原岩形成在太古宙,而1 800Ma 是麻粒岩相降压变质事件的记录,这与华北克拉通前寒武纪高压麻粒岩的年代学一致。威海样品的Sm-Nd 同位素特征则完全不同。矿物和全岩形不成等时线,表现出它们之间的同位素不平衡。ε_Nd(0)值高达+ 127,TDM 模式年龄是1.3Ga.这与Jahn(1994,1996)对威海同类样品的测定结果相同。可以推测威海样品的原岩是元古宙岩石,在后来复杂的变质过程中,在水岩相互作用和岩浆及重熔作用的影响下,同位素系统发生重大变化。同位素年代学为苏鲁变质带和华北克拉通的界限是昆嵛山岩浆-变质杂岩带提供了依据。     

苏鲁造山带东北端石榴辉石麻粒岩的Sm-Nd同位素年代学及其大地构造含义

 大量含石榴石的基性麻粒岩透镜体出露于苏鲁变质带的北部及邻近地区,它们可能是再变质的高压变质岩石。在详细的岩相学研究的基础上,确定采自莱西和文登的样品WD01、WD04、ML06 是由高压麻粒岩经中-高压麻粒岩相再变质形成的,而采自威海的样品WH1 是由柯石英榴辉岩经中-高压麻粒岩相再变质形成的。Sm-Nd 同位素年代学研究也证实了二者的重大差别。3 个高压麻粒岩样品的矿物-全岩内部等时线年龄分别是1 846+ /-76Ma,1 743+ /-79Ma 和1 752+ /-30Ma,TDM 模式年龄是3.3Ga,3.0Ga 和2.8Ga.上述数据说明原岩形成在太古宙,而1 800Ma 是麻粒岩相降压变质事件的记录,这与华北克拉通前寒武纪高压麻粒岩的年代学一致。威海样品的Sm-Nd 同位素特征则完全不同。矿物和全岩形不成等时线,表现出它们之间的同位素不平衡。ε_Nd(0)值高达+ 127,TDM 模式年龄是1.3Ga.这与Jahn(1994,1996)对威海同类样品的测定结果相同。可以推测威海样品的原岩是元古宙岩石,在后来复杂的变质过程中,在水岩相互作用和岩浆及重熔作用的影响下,同位素系统发生重大变化。同位素年代学为苏鲁变质带和华北克拉通的界限是昆嵛山岩浆-变质杂岩带提供了依据。     

Diffusion versus recrystallization processes in Rb-Sr geochronology: Isotopic relics in eclogite facies rocks, Western Gneiss Region, Norway

Rb-Sr and U-Pb isotopic data for granulite facies rocks, forming textural relics with respect to eclogite facies metamorphism in the Western Gneiss Region (WGR) of Norway, highlight the importance of textures and mineral reaction kinetics for the interpretation of geochronological data. Studied rocks from Bårdsholmen, southern WGR, were subjected to granulite facies metamorphism at 955 ± 3 Ma (U-Pb, zircon). Later on, they experienced a subduction-related, kinetically stranded eclogitization (T > 650 °C at ∼20 kbar) at 404 ± 2 Ma (Rb-Sr multimineral internal isochron data), followed by exhumation through amphibolite facies conditions. Full conversion of granulite to eclogite was restricted to zones of fluid infiltration and deformation. Despite the fact that metamorphic temperatures vastly exceeded the commonly assumed ‘closure temperature’ for Rb-Sr in submillimeter-sized biotite for several Ma during eclogite facies overprint, Sr-isotopic signatures of relic biotite have not been fully reset. Large biotite crystals nearly record their Sveconorwegian (Grenvillian) crystallization age. Sr signatures of other granulite facies phases (feldspar, pyroxenes, amphibole) remained unchanged, with the exception of apatite. The results imply that isotopic signatures much closer correspond to the P, T conditions of formation recorded by a dated phase and its paragenesis, than to a temperature history. In texturally well-equilibrated high-grade rocks which experienced no mineral reactions and remained devoid of free fluids during exhumation, like granulites or eclogites, isotopic resetting during cooling is either kinetically locked, or restricted to sluggish intermineral diffusion which demonstrably does not lead to full isotopic homogenization. In texturally unequilibrated rocks, textural relics are likely to represent isotopic relics. It is shown that for both high-grade rocks and for rocks with textural disequilibria, geologically meaningful isotopic ages based on isochron methods can only be derived from sub-assemblages in isotopic equilibrium, which have to be defined by analysis of all rock-forming minerals. Conventional two-point ‘mica ages’ for such rocks are a priori geochronologically uninterpretable, and valid multimineral isochron ages a priori do not record cooling but instead date recrystallization-inducing processes like fluid-rock interaction.     

Geochronological constraints on the polymetamorphic evolution of the granulite‐hosted Challenger gold deposit: Implications for assembly of the northwest Gawler Craton

A temperature‐time history for the granulite‐hosted Challenger gold deposit in the Christie Domain of the Gawler Craton, South Australia, has been derived using a range of isotopic decay systems including U–Pb, Sm–Nd, Rb–Sr and ⁴⁰Ar/³⁹Ar. Nd model ages and detrital zircon ages suggest a protolith age of ca 2900 Ma for the Challenger Gneiss. Gold mineralisation was probably introduced under greenschist/amphibolite‐facies conditions towards the end of the Archaean, between 2800 and 2550 Ma. However, evidence for the exact age and P‐T conditions of this event was almost completely removed by granulite‐facies metamorphism during the Sleafordian Orogeny, which peaked around ca 2447 Ma. Cooling to 350°C occurred before 2060 Ma. It is possible that the Christie Domain was then subject to further sedimentation and volcanism in the period ca 2000–1800 Ma before reburial and a second period of orogeny around ca 1710–1615 Ma. During this second orogeny, the eastern Christie Domain experienced heterogeneous fluid‐induced retrograde metamorphism at lower greenschist‐ to amphibolite‐facies conditions, with metamorphic grade varying between structural blocks. At this time, the Challenger deposit was subject to greenschist‐facies conditions (not significantly hotter than 350°C), while at Mt Christie (50 km to the south) lower amphibolite‐facies conditions prevailed and to the west the Ifould Block experienced extensive plutonism. A third very low‐temperature thermal pulse around ca 1531 Ma, which reached ～ 150–200°C, is recorded at the Challenger deposit. It is likely that the global Grenvillian Orogeny (1300–1000 Ma) was a major period of domain exhumation and juxtaposition.     

桑干地区高压麻粒岩中石榴石和斜长石的连续激光探针~(40)Ar~-~(39)Ar等时年龄及其地质意义

采用微区激光探针４０Ａｒ－３９Ａｒ定年方法, 对华北桑干地区高压基性麻粒岩中变质石榴石和斜长石直接进行了原位微区年代测定。石榴石变斑晶是高压麻粒岩相变质作用形成的矿物,石榴石周围后成合晶反应边组合中的斜长石是石榴石减压分解的产物。石榴石斑晶的４０Ａｒ－３９Ａｒ等时线年龄为２５１０ Ｍａ, 证明高压变质作用发生在太古宙末。斜长石４０Ａｒ－３９Ａｒ等时线年龄为１９６８Ｍａ, 代表石榴石在中压麻粒岩相条件下分解的时代。它们之间年龄相差大于５００Ｍａ, 说明高压麻粒岩可能没有经历近等温减压的ＰＴ轨迹。后成合晶组合很可能代表中压麻粒岩相变质作用的叠加。这一结果对探讨华北克拉通桑干地区早期地壳的构造演化具有重要意义。     

Palaeoproterozoic terrane assembly in the Lewisian Gneiss Complex on the Scottish mainland,south of Gruinard Bay: SHRIMP U–Pb zircon evidence

New SHRIMP U–Pb zircon geochronology and fieldwork integrated with reappraisal of earlier mapping demonstrates that the so-called ‘southern region’ of the mainland Lewisian Gneiss Complex comprises a package of distinct tectono-stratigraphic units. From south to north these are the Rona (3135–2889 Ma), Ialltaig (c. 2000 Ma) and Gairloch (ca. 2200 Ma) terranes. These terranes were metamorphosed and deformed separately until ca. 1670 Ma by which time they had been juxtaposed and were integral with terranes to the north. The northern boundary of the Palaeoproterozoic Gairloch terrane is a shear zone, north of which is the Archaean Gruinard terrane with 2860–2800 Ma protoliths and ca. 2730 Ma granulite facies metamorphism. In contrast, south of the Gairloch terrane, the Archaean gneisses of the Rona terrane have older protolith ages, underwent an anatectic event at ca. 2950 Ma and show no evidence of 2730 Ma granulite facies metamorphism. In current structural interpretations the Gruinard terrane forms a structural klippe over the intervening Gairloch terrane. However, the Rona and Gruinard terranes cannot be equivalent on age grounds, and are interpreted as unrelated different entities. Contained within the southern margin of the Gairloch terrane is the Ialltaig terrane, shown here to comprise an exotic slice of granulite facies Palaeoproterozoic crust, rather than Archaean basement as previously thought. The ca. 1877 Ma granulite facies metamorphism of the Ialltaig terrane is the youngest event that is unique to a single terrane in the mainland Complex, making it an upper estimate for the timing of amalgamation with surrounding tectonic units. U–Pb titanite ages of 1670 ± 12 Ma and ca. 1660 Ma for low-strain zones at Diabaig are interpreted to be cooling through the titanite closure temperature after the amphibolite facies reworking of these southern terranes and the southern margin of the Gruinard Terrane. These new data have implications for the tectonic setting of the mainland in relation to the Outer Hebrides and in the wider evolution of the basement in the North Atlantic.     

从Rb—Sr及K—Ar年龄测定讨论某些前寒武系及中生代火山岩地层的时代

近几年来,为配合寻找富铁矿及其他科研任务,对冀东、辽东、豫西、川西等地的前寒武系,及庐枞、宁芜、繁昌和浙西等地的中生代火山岩地层进行了同位素年龄测定和研究。在所内外的大力支持协助下,进行了野外观察和采样,同时接受了所内外兄弟单位送来的样品及有关地层资料。我们对这些样品进行了同位素年龄测定。冀东、辽东、豫西和川西前寒武纪地层的样品,主要用Rb-Sr全岩等时线法,其中对川西的样品并用了少数K-Ar法。对庐枞、宁芜、繁昌和浙西的中生代地层样品,主要用K-Ar法。对浙西的个别样品并用了Rb-Sr全岩等时线法。对测定得到的部分年龄数据,以前曾以不同方式报道。     

Temporal and tectonic evolution of the granulite-eclogite association from the Bergen Arcs, western Norway

The U-Pb and Sm-Nd dating of deep crustal rocks from the Bergen Arcs system helps resolve enigmatic aspects of the tectonic evolution of the Caledonian Orogen in western Norway and yields insights into the arrested stages of eclogite development within the granulites of the area. The U-Pb dating of zircon from one of the eclogite facies shear zones yields an upper intercept age of 945 ± 5 Ma [all errors two standard deviations (2σ)], which is similar to other zircon ages from the granulite facies protolith. The age is interpreted to represent the time of late Proterozoic (Sveconorwegian) granulite metamorphism. The U-Pb ages of sphene and epidote show that the eclogites formed early in the evolution of the Caledonian Orogen (pre-Scandian phase) at about 460 Ma. An eclogite facies quartz vein yields a Sm-Nd whole rock-garnet isochron of 440 ± 12 Ma that may reflect the onset of cooling immediately after peak eclogite facies conditions, although the Sm-Nd systematics reveal some isotopic disequilibrium within the sample. In tandem with previous ⁴⁰Ar/³⁹Ar age determinations from, an adjacent eclogite of 450 Ma for hornblende and 430 Ma for muscovite, these data indicate that < 30 Ma elapsed between formation of the eclogites and the initial stages of cooling and exhumation to at least mid-crustal levels. This corresponds to minimum cooling rates of 14 °C/m.y. The timing relations suggest that the formation and exhumation of these eclogites from the overlying Caledonian Nappe wedge in western Norway are related to an early phase of crustal subduction during or somewhat before the major phase of continent-continent collision.

The short period of time between the formation of the eclogites and the initial stages of exhumation and rapid cooling is consistent with the only partial and localized transformation of the granulite to eclogite. Isolated occurrences of eclogite within the granulite, the formation of eclogite along metasomatic fronts and the formation of hydrous eclogite facies minerals within the “dry” granulite all point to the importance of fluids in the transformation and re-equilibration of the granulite to eclogite. Together, field and isotopic data demonstrate that both the localized and limited access of fluids and the rapid cycling of continental crust through the deepest portions of the orogen to upper crustal levels resulted in the preservation of the arrested stages of eclogite formation and survival of the granulites metastably through eclogite facies conditions.