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1.
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 总被引:28,自引:25,他引:3
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。 相似文献
2.
川西沙坝麻粒岩的Sm-Nd和Rb-Sr同位素年龄及其地质意义 总被引:15,自引:2,他引:15
首次测定扬子板块西缘古老的结晶基底岩石沙坝麻粒岩Sm Nd矿物等时线年龄为 114 0± 110Ma ,代表中元古代末期麻粒岩相变质作用时代。Rb -Sr矿物等时线年龄为 2 18± 11Ma ,可能为晚古生代至早中生代基性岩浆侵入的热扰动改造年龄。其亏损地幔模式年龄TDM 为115 8Ma ,表明沙坝麻粒岩的原岩在成岩之后不久即经受麻粒岩相变质作用。根据上述年龄以及紫苏辉石中Nd同位素封闭温度和40 Ar/ 3 9Ar年龄等资料的计算表明 ,以沙坝麻粒岩为代表的下地壳岩石抬升运动速率是缓慢的 相似文献
3.
华夏地块与扬子地块的拼合时限与方式长期存在争议。本文对出露于浙江诸暨一带的原"陈蔡岩群"进行了详细的露头尺度解剖。野外地质调查表明,原"陈蔡岩群"主要由不同性质的外来岩块与基质组成。其中:代表外来岩块的大理岩及斜长角闪岩的变质年龄分别为(424.7±2.9)和(420.6±1.8)Ma,成岩年龄分别为(479.2±9.5)~(424.7±2.9)Ma和(507.7±7.8)~(420.6±1.8)Ma,斜长角闪岩原岩为具OIB(洋岛玄武岩)特征的碱性玄武岩,大理岩的原岩为海相碳酸盐岩,二者共同构成了洋岛海山组合。代表原地岩块的变长石石英砂岩主要物源区为3 620~1 530 Ma形成于活动大陆边缘和大陆岛弧环境下的古老地壳物质;与之构造混杂接触的斜长角闪岩变质年龄为(438.0±2.5)Ma,其原岩分别为形成于消减带岛弧环境的岛弧拉斑玄武岩、形成于俯冲环境下的富Nb玄武岩和洋岛海山环境下的具OIB特征的碱性玄武岩类。代表基质的含榴黑云斜长片麻岩LA-MC-ICP-MS锆石U-Pb年龄测试结果表明,其变质年龄为(441.0±3.0)Ma,碎屑206Pb/238U年龄多数为840~780 Ma,反映其物源主要来自于新元古代,且最年轻的沉积年龄限定在598 Ma,说明片麻岩原岩可能为早古生代沉积地层。陈蔡地区该套岩石组合的发现表明,原"陈蔡岩群"的构造属性应为早古生代俯冲增生杂岩。结合测区及龙游地区新发现的加里东期麻粒岩和退变榴闪岩,提出扬子与华夏两大地块碰撞于445~420 Ma。 相似文献
4.
胶东地块西部变质岩锆石U-Pb定年和氧同位素研究 总被引:9,自引:10,他引:9
对胶东地块西部变质岩作了系统的锆石U-Pb定年和矿物氧同位素分析,结果对这些变质岩的原岩性质和变质时代提供了制约。研究得到:(2)2个TTG片麻岩的原岩谐和年龄分别为2692±14Ma和2691±12Ma,部分锆石记录了1.7Ga~1.8Ga左右的变质事件。岩浆锆石δ~(18)O值为5.11~5.55‰,指示TTG岩浆在成因上与幔源岩石关系密切;(2)呈透镜状包体分布于TTG片麻岩中的斜长角闪岩全岩δ~(18)O估计值总体在6.0~6.5‰之间,表明斜长角闪岩原岩同样具幔源性质,其原岩初始氧同位素组成总体未受后期变质作用改造,但局部有低δ~(18)O值(3.6‰)斜长角闪岩分布,指示胶东地块西部同样存在δ~(18)O亏损事件;(3)粉子山群长英质副片麻岩具有较高的氧同位素组成,全岩δ~(18)O估计值在12.3~14.5‰之间,锆石δ~(18)O值高达9.92‰,指示其源区物质为高δ~(18)O值表壳岩。粉子山群斜长角闪岩全岩δ~(18)O估计值在5.5‰左右,表明其原岩具有幔源性质,原岩初始氧同位素组成也未受后期变质作用的明显改造;(4)粉子山群混合岩化变质作用时间为1748±22Ma,斜长角闪质混合岩中变质新生锆石δ~(18)O值为6.07‰,长英质混合岩中变质新生锆石δ~(18)O值为6.88~7.67‰,指示在混合岩化变质作用过程中有外部高δ~(18)O值流体加入,引起混合岩氧同位素组成不同程度地升高;(5)粉子山群中橄榄大理岩岩浆核锆石U-Pb不一致线上、下交点年龄分别为769±48Ma和215±34Ma,分别代表岩浆锆石结晶年龄和变质年龄,说明胶东地块西部同样存在新元古代岩浆活动,并遭受到三叠纪变质作用;(6)分布于TTG片麻岩中的基性麻粒岩原岩年龄为2379±54Ma,麻粒岩相变质作用时间为1794±41Ma,与混合岩化变质作用时间基本一致。麻粒岩相变质锆石δ~(18)O值为4.75‰,氧同位素研究表明基性麻粒岩原岩具幔源性质,其原岩氧同位素组成未受到后期变质作用改造。胶东地块西部新元古代岩浆活动、印支期变质时代和~(18)O亏损事件的产出指示,胶东地块西部有可能属于扬子板块,对应于扬子板块北缘新元古代裂谷岩浆侵位时裂谷肩部的北翼古老围岩。在印支期陆壳俯冲过程中,整个胶东地块西部可能并没有俯冲到地幔深度。 相似文献
5.
北祁连造山带是典型的早古生代增生型造山带,具有典型增生型造山带的"沟-弧-盆"体系。祁连地块位于北祁连造山带南部,由深变质的前寒武纪基底和新元古代到中生代的沉积盖层组成。在连祁地块北缘门源宝库河附近延伸数千米的变基性岩(主体为斜长角闪岩和角闪岩)中识别出了基性麻粒岩,峰期矿物组合为石榴子石+斜长石+钾长石+普通辉石+角闪石+钛铁矿+石英,相平衡模拟计算结果显示峰期温压条件为P=10.6kbar、T=800℃,峰期之后经历了近等温降压的P-T轨迹。锆石LA-ICP-MS U-Pb年代学结果显示变基性岩的原岩结晶年龄分别为1110±18Ma和1140±30Ma,变质年龄分别为478.2±3.9Ma和469±4.6Ma,结合近等温降压的P-T轨迹,469~478Ma的变质年龄应近似代表了麻粒岩相变质作用时代。结合区域资料,我们认为早古生代北祁连洋存在南北双向俯冲极性,祁连洋南向俯冲使得祁连地块前寒武纪基底在早古生代再活化。变基性岩的原岩年龄与祁连地块南部欧龙布鲁克地块(全吉地块)中发现的变基性岩和花岗质片麻岩原岩年龄及副片麻岩的变质年龄一致,均为~1100Ma,表明祁连地块与欧龙布鲁克地块一起卷入了格林威尔造山事件。 相似文献
6.
北大别黄土岭麻粒岩锆石U—Pb离子探针定年 总被引:28,自引:6,他引:28
阴极发光显微结构分析表明 ,北大别黄土岭麻粒岩中存在三种类型的锆石 :原岩锆石、麻粒岩相锆石和残留锆石。对它们分别进行离子探针定年 ,得到黄土岭麻粒岩的原岩年龄约为 2 70 0 Ma、麻粒岩相变质事件的年龄为 2 0 5 2± 10 0 Ma、残留锆石的年龄为约 3.4 Ga。以上研究表明黄土岭麻粒岩为残存的扬子板块的结晶基底 ,而约 3.4 Ga残留锆石的发现 ,则首次证明大别山地区存在古太古代的陆壳物质 相似文献
7.
为了搞清大别山地区高压麻粒岩和高压超高压榴辉岩的关系,了解大别山地区加里东期构造-热事件的性质和特征,探索大别造山带的区域延伸和对比等,选择大别山东部惠兰山麻粒岩及安徽太湖石马榴辉岩的直接围岩——含榴斜长片麻岩进行了同位素年代学研究。惠兰山麻粒岩呈似层状夹于长英质片麻岩中,岩性为石榴角闪二辉麻粒岩,其峰变质条件t=682~880℃;P=0.9~1.29 GPa,峰变质压力与大别山西部熊店加里东期榴辉岩相当。惠兰山麻粒岩存在两类不同晶形特征和不同成因的锆石。其中长柱状锆石用~(207)Pb/~(206)Pb蒸发法给出平均年龄443±23 Ma,代表了麻粒岩相峰变质年龄;浑圆粒状锆石用同样方法给出的年龄为2300±15 Ma,可能反映麻粒岩原岩形成年龄或前期变质事件的时代。石马含榴斜长片麻岩 相似文献
8.
中国东北麻山杂岩晚泛非期变质的锆石SHRIMP年龄证据及全球大陆再造意义 总被引:43,自引:1,他引:43
中国东北地区佳木斯地块南部麻山杂岩正、副片麻岩 7个样品的锆石 SHRIMP年龄数据首次明确地表明 ,东北地区存在 500 Ma的晚泛非期高级变质作用事件。峰期麻粒岩相变质导致柳毛地区 (502± 10)Ma (2σ )深熔花岗岩的形成。正、副片麻岩变质年龄的一致性表明它们已在变质前发生了构造叠置。西麻山副片麻岩中含有在后期麻粒岩相变质过程中未重结晶的碎屑锆石,由此形成从协和一致的 550 Ma到弱不一致 1 900 Ma的较大 207Pb/206Pb年龄变化范围,表明其原岩具有从新元古代到中元古代-古元古代的年龄。柳毛地区变质的片麻状闪长岩中所含的古老锆石的 207Pb/206Pb年龄为 546~ 1 460 Ma表明,该闪长岩大约在 1 400 Ma就位,并受到 500 Ma变质事件的影响,从而说明柳毛地区存在中元古代基底。然而,与以前的认识相反,麻山杂岩不存在具有太古宙基底的同位素证据。晚泛非期变质事件年龄的确定对重塑晚前寒武纪-显生宙早期麻山杂岩和佳木斯地块的古地理位置具有重要意义。根据目前获得的有关证据,认为佳木斯地块可能曾经位于冈瓦纳大陆北缘的华北克拉通附近。 相似文献
9.
张广才岭东侧英城子金矿区早古生代花岗岩锆石U-Pb年龄及地质意义 总被引:2,自引:0,他引:2
本文首次对佳木斯地块西缘、张广才岭东侧英城子金矿区出露的大面积黑云母碱长花岗岩,进行了锆石LA-ICP MS U-Pb年代学精细研究。实验共获得四组单颗粒锆石U-Pb谐和年龄,它们分别为612±4Ma、495.2±2.7Ma、476.8±5.5Ma和431±3Ma;其中612±4Ma具有指示晚元古代增生地壳过程形成的花岗岩锆石特征,495.2±2.7Ma的U-Pb年龄与区域内麻山群的变质作用时间相吻合,431±3Ma的年龄与早古生代晚期的区域变质作用时间吻合,而476.8±5.5Ma的锆石年龄则代表黑云母碱长花岗岩的真实结晶年龄。这项成果记录了该地区在中一新元古代时期曾发生过重要的地壳增生事件,增生后的地壳被打开形成大洋;至早古生代早期,两侧的地体发生拼贴,引起区域麻山群发生麻粒岩相的变质作用、形成花岗质片麻岩;在早古生代晚期,佳木斯地块西缘的陆间洋最终闭合,形成具有壳源特征同碰撞花岗岩,之后的韧性变形作用可能为金矿床的形成提供了有利条件。 相似文献
10.
滇西高黎贡山群变质岩的锆石年龄及其构造意义 总被引:11,自引:5,他引:6
被认为是腾冲-梁河地块前寒武纪结晶基底的滇西高黎贡山群变质岩系,其原岩及变质时代长期争论不休。岩相学和地球化学表明,组成高黎贡山群的黑云二长片麻岩、黑云角闪斜长片麻岩和变粒岩的原岩均为岩浆岩。首次对这些变质岩进行原位锆石U-Pb定年,分别获得497.8±7.2Ma~500±14Ma、83.5±0.9Ma的岩浆结晶年龄和459±5Ma、55.2±1.1Ma的变质年龄。结合相邻区碎屑锆石年龄及其区域对比分析,认为腾冲-梁河地块高黎贡山群中以石英片岩、石英岩为主体的原始沉积岩系可能形成于新元古代,应与拉萨地块有密切的亲缘关系。在早古生代环冈瓦纳大陆周缘造山过程中被寒武纪花岗岩侵入并发生变质作用;在新特提斯俯冲过程中,经历了晚中生代的安第斯型造弧作用;在印度与欧亚大陆碰撞过程中,又经历了新生代的岩浆作用、变质作用以及走滑剪切形成糜棱岩化作用。 相似文献
11.
The Napier Complex of Enderby and Kemp Lands forms the north-western part of the East Antarctic Shield and consists predominantly of gneisses and granulites metamorphosed during a ca. 2.8 Ga high-grade and a ca. 2.5 Ga ultra-high temperature event. The western segment of the Napier Complex includes coastal outcrops, islands and nunataks around Amundsen and Casey Bays, and the Tula Mountains. This region records some of the highest metamorphic temperatures measured on Earth, affecting a variety of gneisses as old as ca. 3.8 Ga. Five samples of orthogneiss from the less-studied eastern Tula Mountains, including three granitic, one trondhjemitic and one dioritic gneiss, were dated by zircon U-Pb Secondary Ion Mass Spectrometry (SIMS). The three orthogneisses yield protolith ages of 3750 ± 35 Ma (granitic), 3733 ± 21 (trondhjemitic) Ma and 3560 ± 42 Ma (dioritic), whereas the two other granitic orthogneisses record ages of 2903 ± 14 Ma and 2788 ± 24 Ma. Zircon growth during metamorphism occurred at 2826 ± 10 Ma, and also between 2530 Ma and 2480 Ma. Samples from the Tula Mountains can be geochemically subdivided into Y-HREE-Nb-Ta depleted and undepleted groups. Eoarchean granitoids are included in both geochemical groups, as are Meso- and Neoarchean granitoids. The Y-HREE-Nb-Ta depleted granitoids can be generated by medium- to high-pressure melting of mafic crust, whereas undepleted granitoids can be generated by low-pressure melting. However, relatively high potassium contents in most samples, and the presence of xenocrystic/inherited zircon in some, reflect the likely involvement of felsic crustal sources. This diversity in granitoid composition occurs across the Napier Complex. The lack of a simple correlation between protolith age and geochemical type is an indication that magmatism during the Eoarchean (and later) involved diverse sources and processes, including re-melting and recycling of various crustal components, rather than just the formation of juvenile crust. 相似文献
12.
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 总被引:12,自引:9,他引:3
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. 相似文献
13.
In the Rogaland–Vest Agder terrain of the Sveconorwegian Province of SW Norway, two main Sveconorwegian metamorphic phases
are reported: a phase of regional metamorphism linked to orogenic thickening (M1) and a phase of low-pressure thermal metamorphism
associated with the intrusion of the 931 ± 2 Ma anorthosite-charnockite Rogaland igneous complex (M2). Phase M1 reached granulite
facies to the west of the terrane and M2 culminated locally at 800–850 °C with the formation of dry osumilite-bearing mineral
associations. Monazite and titanite U-Pb geochronology was conducted on 17 amphibolite- to granulite-facies orthogneiss samples,
mainly from a suite of 1050 +2/−8 Ma calc-alkaline augen gneisses, the Feda suite. In these rocks, prograde negatively discordant monazite crystallized during
breakdown of allanite and titanite in upper amphibolite facies at 1012–1006 Ma. In the Feda suite and other charnockitic gneisses,
concordant to slightly discordant monazite at 1024–997 Ma probably reflects breakdown of biotite during granulite-facies M1
metamorphism. A spread of monazite ages down to 970 Ma in biotite ± hornblende samples possibly corresponds to the waning
stage of this first event. In the Feda suite, a well defined monazite growth episode at 930–925 Ma in the amphibolite-facies
domain corresponds to major clinopyroxene formation at the expense of hornblende during M2. Growth or resetting of monazite
was extremely limited during this phase in the granulite-facies domain, up to the direct vicinity of the anorthosite complex.
The M2 event was shortly followed by cooling through ca. 610 °C as indicated by tightly grouped U-Pb ages of accessory titanite
and titanite relict inclusions at 918 ± 2 Ma over the entire region. A last generation of U-poor monazite formed during regional
cooling below 610 °C, in hornblende-rich samples at 912–904 Ma. This study suggests: (1) that monazite formed during the prograde
path of high-grade metamorphism may be preserved; (2) that monazite ages reflect primary or secondary growth of monazite linked
to metamorphic reactions involving redistribution of REEs and Th, and/or fluid mobilisation; (3) that the U-Pb system in monazite
is not affected by thermal events up to 800–850 °C, provided that conditions were dry during metamorphism.
Received: 9 January 1997 / Accepted: 15 April 1998 相似文献
14.
A. B. Roy Alfred Kröner Sanjeev Rathore Vivek Laul Ritesh Purohit 《Journal of the Geological Society of India》2012,79(4):323-334
Several bodies of granulites comprising charnockite, charno-enderbite, pelitic and calc-silicate rocks occur within an assemblage of granite gneiss/granitoid, amphibolite and metasediments (henceforth described as banded gneisses) in the central part of the Aravalli Mountains, northwestern India. The combined rock assemblage was thought to constitute an Archaean basement (BGC-II) onto which the successive Proterozoic cover rocks were deposited. Recent field studies reveal the occurrence of several bodies of late-Palaeoproterozoic (1725 and 1621 Ma) granulites within the banded gneisses, which locally show evidence of migmatization at c. 1900 Ma coeval with the Aravalli Orogeny. We report single zircon ‘evaporation’ ages together with information from LA-ICP-MS U-Pb zircon datings to confirm an Archaean (2905 — ca. 2500 Ma) age for the banded gneisses hosting the granulites. The new geochronological data, therefore, suggest a polycyclic evolution for the BGC-II terrane for which the new term Sandmata Complex is proposed. The zircon ages suggest that the different rock formations in the Sandmata Complex are neither entirely Palaeoproterozoic in age, as claimed in some studies nor are they exclusively Archaean as was initially thought. Apart from distinct differences in the age of rocks, tectono-metamorphic breaks are observed in the field between the Archaean banded gneisses and the Palaeoproterozoic granulites. Collating the data on granulite ages with the known tectono-stratigraphic framework of the Aravalli Mountains, we conclude that the evolution and exhumation of granulites in the Sandmata Complex occurred during a tectono-magmatic/metamorphic event, which cannot be linked to known orogenic cycles that shaped this ancient mountain belt. We present some field and geochronologic evidence to elucidate the exhumation history and tectonic emplacement of the late Palaeoproterozoic, high P-T granulites into the Archaean banded gneisses. The granulite-facies metamorphism has been correlated with the thermal perturbation during the asymmetric opening of Delhi basins at around 1700 Ma. 相似文献
15.
V. A. Glebovitsky A. B. Kotov E. B. Sal’nikova A. M. Larin S. D. Velikoslavinsky 《Geotectonics》2009,43(4):253-263
The available data on the age and formation conditions of the granulite complexes in the western Dzhugdzhur-Stanovoi Fold Region (Dambuki and Larba blocks) and the adjacent territory of the Peristanovoi Belt (Kurul’ta, Zverevsky, and Sutam blocks) are systematized. At least three Early Precambrian episodes of high-grade granulite-facies metamorphism dated at 2.85–2.83, 2.65–2.60, and 1.90–1.88 Ga are established in the geological history of the western Dzhugdzhur-Stanovoi Fold Region. Five granulite-facies metamorphic events are documented in the Peristanovoi Belt. The early granulite-facies metamorphism, migmatization, and emplacement of charnockite are related to the first event (2183 ± 1 Ma) in the Kurul’ta Block. The structural transformation and metamorphism of charnockite under conditions of granulite facies correspond to the second event (2708 ± 7 Ma). The enderbite belonging to the Dzhelui Complex (2627 ± 16) and charnockite of the Altual Complex (2614 ± 7 Ma) were emplaced during the third tectonic event, which was immediately followed by the emplacement of the Kalar anorthosite-charnockite complex (2623 ± 23 Ma). The first episode of Early Proterozoic granulite-facies metamorphism of the Sutam Sequence in the tectonic block of the same name was related to the fourth event, probably caused by collision of the Olekma-Aldan continental microplate and the passive margin of the Uchur continental microplate. Finally, granulite-facies metamorphism superimposed on rocks of the Kalar Complex in the Kurul’ta Block and high-pressure metamorphism in the Zverevsky and Sutam blocks (1935 ± 35 Ma) correspond to the fifth metamorphic event. The Late Archean metamorphic events are most likely related to the amalgamation and subsequent collision of the terranes which currently make up the granulite basement of the Dzhugdzhur-Stanovoi Fold Region with the Olekma-Aldan continental microplate. In the Early Proterozoic, the Aldan Shield and the Dzhugdzhur-Stanovoi Fold Region were separated by an oceanic basin. Its closure, and the collision of the Aldan and Stanovoi continental microplates, were accompanied by granulite-facies metamorphism and led to the formation of the Peristanovoi Belt, or Peristanovoi Suture Zone. This collision suture continued functioning in the Phanerozoic (from the Early Jurassic to the Early Cretaceous) with the formation of thick shear zones and greenschist retrograde metamorphism. 相似文献
16.
JIAN Ping YANG Weiran ZHANG Zichao Institute of Geology CAGS Baiwanzhuang R Beijing China University of Geosciences Wuhan Hubei Yichang Institute of Geology Mineral Resources CAGS Yichang Hubei 《《地质学报》英文版》1999,73(1):78-83
The Huangtuling hypersthene-garnet-biotite gneiss at Luotian County, Hubei Provine, is a typicalgranulite-facies rock of the Dabie Group Complex in the Dabie orogenic belt. Investigations on the morphology andoccurrence of zircons and their internal structures shown in the thin sections lead to the recognition of three types ofzircons, which are in good agreement with the types identified on the basis of morphology, colour and external fea-tures from the related zircon concentrates. The observation of zircons in the rock reveals that part of type 1 zirconsshow signs of a double-layered structure. The interval part existed in the protolith prior to the granulite-facies meta-morphism. Type 2, the prismatic zircons which mainly occur in garnet and hypersthene are metamorphic minerals ofthe granulite-facies metamorphism. Type 3, the round multifaceted zircons in felsic minerals and biotite, are proba-bly attributed to a later geological event related to migmatization. The ~(207)Pb/~(206)Pb zircon dating by direct evaporationon (thermal evaporation ion mass spectrometer) yields ages ranging from 2814 Ma to 1992 Ma. The age discrepancyamong these different zircon types is conspicuous. The yellow-brown(type 1) zircons give ages of 2814±29 Ma to2527±6 Ma, the prismatic euhedral zircons (type 2), 2456±7 Ma to 2254±4 Ma, and the round multifaceted zircons(type 3), 1992±10 Ma. The results are geologically interpreted in consideration of the complicated behaviours of zir-cons during Precambrian geological evolution of the Dabie area. (1) If the protolith of the gneiss is a sedimentaryrock, then type 1 zircons are clastic ones and the ages 2814±29 Ma and 2811±27 Ma may reflect the minimum age ofthe rocks of its source region. also the first geological event in the area. Sedimentation of the protolith occurred be-tween 2814 Ma and 2527 Ma, probably close to 2814 Ma. If the protolith is a volcanic rock, then the formation age ofthe supracrustal rocks of the Dabie Group Complex is around 2814 Ma. The age 2456±7 Ma reflects the time whenthe granulite-facies metamorphism took place. The later migmatization event is dated at aboat 1992±10 Ma, and isprobably the latest early Precambrian event in the area. The present work provides geochronological evidence for the existence of the Dabie Archaean craton, whichhad probably experienced 3 or 4 geological events during its early Precambrian evolution. 相似文献
17.
The RbSr and UPb methods were used to study gneisses in the Lake Helen quadrangle of the Big Horn Mountains, Wyoming. Two episodes of magmatism, deformation and metamorphism occurred during the Archean. Trondhjemitic to tonalitic orthogneisses and amphibolite of the first episode (E-1) are cut by a trondhjemite pluton and a calc-alkaline intrusive series of the second episode (E-2). The E-2 series includes hornblende-biotite quartz diorite, biotite tonalite, biotite granodiorite and biotite granite.A RbSr whole-rock isochron for E-1 gneisses indicates an age of 3007 ± 34 Ma (1 sigma) and an initial 87Sr/86Sr of 0.7001 ± 0.0001. UPb determination on zircon from E-1 gneisses yield a concordia intercept age of 2947 ± 50 Ma. The low initial ratio suggests that the gneisses had no significant crustal history prior to metamorphism, and that the magmas from which they formed had originated from a mafic source.A RbSr whole-rock isochron for E-2 gneisses gives an age of 2801 ± 31 Ma. The 87Sr/86Sr initial ration is 0.7015 ± 0.0002 and precludes the existence of the rocks for more than 150 Ma prior to metamorphism. The E-2 magmas may have originated from melting of E-1 gneisses or from a more mafic source. 相似文献
18.
中条山前寒武纪岩石是洞悉华北克拉通前寒武纪基底构造演化的重要窗口之一,该区的前寒武纪岩系主要由涑水杂岩、绛县群、中条群、担山石群,以及西阳河群和汝阳群组成.本文以中条山地区涑水杂岩中古元古代花岗质片麻岩为研究对象,挑选其中的变形变质白云母进行激光40Ar/39Ar和常规40Ar/39Ar测年分析.激光40Ar/39Ar法获得的白云母等时年龄1830Ma±20Ma为白云母氩封闭温度年龄的最小估计,常规40Ar/39Ar法给出的白云母坪年龄1852Ma±11Ma为白云母氩封闭温度年龄的最佳估计.白云母1852Ma± 11Ma与先前获得的独居石电子探针U-Th-Pb主峰值年龄相近,并且与华北克拉通中部带的变质年龄一致,表明中条山地区涑水杂岩中古元古代花岗质片麻岩记录了古元古代晚期的一次变质作用事件.这一事件与华北克拉通中部怀安-吕梁-恒山-五台-赞皇等地的变质变形作用同时发生,揭示华北克拉通东、西部陆块沿中部带的碰撞拼合应发生在古元古代晚期,而非新太古代. 相似文献
19.
北阿尔金拉配泉米兰群片麻岩及其中两期基性岩墙群LA-ICP-MS锆石U-Pb年龄及地质意义 总被引:2,自引:1,他引:1
北阿尔金拉配泉北侧米兰群混合角闪斜长片麻岩被2期基性岩墙群(辉绿玢岩和棕闪煌斑岩)侵位。本次分别对三者进行了LA-ICP-MS锆石U-Pb同位素侧年。混合岩化角闪斜长片麻岩中锆石结晶年龄为2007Ma±25Ma,结合西北地区2.0Ga左右广泛的构造-热事件,可能与Columbia超大陆汇聚有关。辉绿玢岩和棕闪煌斑岩的年龄结构相似,锆石较老年龄组分分别为1962~2093Ma和1804~2038Ma,系在侵位时从围岩(混合角闪斜长片麻岩)中捕获的锆石的年龄;最年轻的年龄组分(79~94Ma)代表基性岩墙群的侵位时间,与阿尔金北缘断裂伸展活动有关;古生代年龄(288~504Ma)为岩墙群上侵过程中同化混染北阿尔金蛇绿混杂岩带部分岩石的年龄。 相似文献
20.
内蒙古达茂旗花岗岩类LA-ICP-MS
锆石U-Pb年龄及其地质意义 总被引:2,自引:1,他引:1
对内蒙古达茂旗北部构造单元的巴特敖包岛弧带2个花岗闪长岩岩体样品和南部构造单元一个花岗岩岩体的2件样品进行了LA-ICP-MS锆石U-Pb定年。北部构造单元采自2个花岗闪长岩岩体的样品锆石206Pb/238U年龄分别为468Ma±2Ma和452Ma±3Ma,代表了这2个岩体的侵位时间,表明古亚洲洋向华北克拉通之下俯冲不晚于468Ma±2Ma;南部构造单元采自同一花岗岩岩体的2件样品获得的锆石206Pb/238U年龄分别为268Ma±2Ma和264Ma±2Ma,和该单元西部岩体已有的锆石年龄相符。这为华北克拉通北缘岩浆作用研究提供了新的年代学证据。 相似文献