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1.
云开地块中生代构造演化是华南地区的研究热点之一.通过对云开地块变质基底中的混合岩、片麻岩(5个样品)和花岗岩(1个样品)开展锆石LA-ICP-MS U-Pb定年,获得440.3±3.3 Ma、230.2±2.9 Ma、230.7±1.3 Ma、459.5±2.7 Ma、431.5±4.3 Ma、229.2±5.4 Ma、229.7±2.7 Ma 7组变质(深熔)或岩浆年龄和2组(样品1432-1和ID7-3)碎屑锆石年龄,碎屑锆石年龄范围均为太古代-新元古代,且具有~1.0 Ga年龄主峰,与天堂山岩群和云开群碎屑锆石年龄谱相似.区域资料表明云开地块天堂山岩群和云开群具有相似的物质组成,均形成于早古生代-新元古代,存在变质程度和物质面貌的差异;在加里东期构造-热事件的基础上,广泛叠加了印支期区域变质(深熔)-构造-流体作用影响.4个样品中(1431-1、1432-1、D116-3和ID7-3)锆石原位Lu-Hf同位素组成显示,加里东期变质和深熔锆石Lu/Hf同位素组成基本一致,应继承了原岩的同位素组成特征.印支期变质和深熔锆石Lu/Hf同位素组成不同,可能主要由变质作用和深熔作用的差异所致.以古-中元古代为主的地壳物质参与了加里东期和印支期变质-深熔作用,在加里东期和印支期深熔作用过程中,均有少量幔源物质的加入,印支期幔源物质的贡献相对显著. 相似文献
2.
前寒武纪变沉积岩系是阿拉善地块重要组成部分,准确测定其原岩成岩时代和变质时代,对于进一步认识阿拉善地块起源、形成、演化与亲缘性具有十分重要的科学意义.本文对阿拉善地块东部阿拉坦敖包地区德尔和通特组含蓝晶石石榴云母石英片岩开展了系统的野外地质调查、岩相学观察和同位素年代学研究.碎屑锆石U-Pb定年和野外地质调查表明,阿拉坦敖包地区德尔和通特组和祖宗毛道组碎屑锆石年龄介于3 306~1 146 Ma,并以出现中元古代锆石年龄(1 800~1 100 Ma)高频区为特征,最小一组碎屑锆石年龄约为1 123 Ma,结合区域上它们被约900 Ma花岗质片麻岩侵入的野外关系,阿拉坦敖包地区德尔和通特组与祖宗毛道组变沉积岩系的沉积时代被限定在1 123~900 Ma之间,为一套中元古代晚期?新元古代早期陆缘沉积建造,具有亲华北板块的特点.此外,变质独居石和变质锆石U-Pb定年和微量元素分析表明,阿拉坦敖包地区德尔和通特组含蓝晶石泥质片岩中发育大量变质独居石,它们具有典型变质独居石的稀土元素配分模式(轻稀土元素强烈富集而重稀土元素强烈亏损),其加权平均年龄为419±3 Ma(MSWD=7.1,n=40),类似地,一个锆石变质边也记录了406±7 Ma的206Pb/238U年龄.这些变质年龄被解释为阿拉善地块东部阿拉坦敖包地区德尔和通特组含蓝晶石石榴云母石英片岩遭受早古生代末角闪岩相变质?变形作用的时代,可能是阿拉善地块与周缘微陆块早古生代末碰撞造山作用的响应. 相似文献
3.
北秦岭造山带早古生代多期变质与深熔作用:锆石U-Pb年代学证据 总被引:5,自引:4,他引:1
北秦岭造山带中的秦岭群以多期变质作用和强烈混合岩化为特征,出露有早古生代的榴辉岩和高压麻粒岩,以及区域性分布的中低压麻粒岩-角闪岩相变质岩石和混合岩。本文对西峡双龙地区混合岩化片麻岩(中色体)、石榴子石黑云母片岩(暗色体)和淡色花岗岩脉体进行了详细的锆石U-Pb定年和微量元素研究。结果表明片麻岩的原岩年龄为941±11Ma(2σ,MSWD=0.59),石榴子石黑云母片岩的原岩年龄为756±9.9Ma(2σ,MSWD=1.07)。石榴子石黑云母片岩中的变质锆石获得了484±9.6Ma(2σ,MSWD=0.88)的年龄,与片麻岩中锆石变质增生边获得的单点年龄498±11Ma在误差范围内一致。这些变质锆石多数具有平坦的HREE分配模式,弱Eu负异常,与高压变质岩中的变质锆石特征相似。该年龄与秦岭榴辉岩和高压麻粒岩的变质年龄相一致。石榴子石黑云母片岩中锆石的最外层增生边记录了424±9.1Ma的年龄,同时淡色脉体中的锆石也给出了422±4.0Ma(2σ,MSWD=0.77)的加权平均年龄,代表了深熔脉体的结晶年龄。这些锆石均为新生锆石,阴极发光弱,具有低的Th/U比值,平坦的HREE分配模式,强烈的Eu负异常,指示部分熔融过程中存在大量石榴子石和斜长石。深熔脉体的年龄与秦岭群中的中低压高温-超高麻粒岩相变质的年龄相符。结合已有的结果,我们认为秦岭群普遍记录了500~480Ma的高压、超高压变质作用,并叠加了440~400Ma的中压-高温变质和深熔作用。秦岭群可能是Rodinia超大陆裂解过程中从华南陆块或相似构造属性陆块分离并漂移到华北克拉通南缘的微陆块。在500~480Ma时发生碰撞造山作用导致北秦岭微陆块深俯冲并发生了高压-超高压变质作用,在志留纪由于商丹洋壳北向俯冲导致秦岭微陆块发生了以中压-高温变质、深熔和同时的岩浆作用为特征的增生造山作用。 相似文献
4.
以出露于石鼓-黎明地区的黑云母石英片岩及其深熔脉体为重点研究对象,对其中的锆石进行了阴极发光图像分析、SHRIMP和LA-ICP-MS U-Pb年代学研究。阴极发光图像显示,黑云母石英片岩中大部分锆石保留清晰的振荡环带;深熔脉体中大部分锆石具有核-边结构,核部保留清晰的振荡环带或呈灰色无分带结构,边部较窄呈黑色。对黑云母石英片岩及其深熔脉体中锆石核部进行定年,得到年龄范围为2 637~743 Ma,具有858~852 Ma的主要年龄峰值,表明其主要物质来源为扬子板块西缘新元古代岩浆岩,同时也有太古代-古元古代基底岩石的加入,沉积时代应晚于852 Ma。深熔脉体锆石边部的Th/U值较小(0. 1),得到206Pb/238U年龄变化于225~197 Ma之间,可能代表了变沉积岩的变质-深熔时代,该年龄与金沙江-点苍山-哀牢山变质带二叠纪-三叠纪变质事件的时代相一致。 相似文献
5.
南天山北缘榆树沟麻粒岩的变质作用及其锆石SHRIMP年龄的研究 总被引:3,自引:2,他引:1
南天山北缘榆树沟麻粒岩主要为基性麻粒岩,由多个变质程度不同(低、中、高压麻粒岩相)的岩片被构造作用拼贴到一起。本文对不同麻粒岩开展详细的岩相学研究,识别出的变质作用有:进变质角闪岩相、低压麻粒岩相、中压麻粒岩相、高压麻粒岩相和退变质的中压麻粒岩相、角闪岩相、绿片岩相变质作用。对于有成熟温压计的中压麻粒岩相(即Grt-Opx-Cpx-Plg-Qtz组合)矿物组合的样品进行了温压估算,获得的温度和压力范围为724~826℃和0.64~0.88GPa。对原岩为火山岩的中压麻粒岩相岩石的锆石核部的研究表明,锆石的来源复杂;SHRIMP锆石U-Pb年代学测定显示,锆石的变质生成边的年龄稳定,为390~401Ma,代表了中压麻粒岩相进变质作用的时代。 相似文献
6.
错那洞穹隆是藏南特提斯喜马拉雅地区新发现的一个片麻岩穹隆构造。穹隆核部发育一套早古生代眼球状片麻岩。本文在野外地质调查的基础上,利用LA-(MC)-ICP-MS对花岗质片麻岩2个样品的锆石开展U-Pb年代学和Lu-Hf同位素分析。片麻岩中的锆石发育核-幔-边结构,核部为具溶蚀港湾结构的继承锆石,幔部为具韵律(震荡)环带的岩浆锆石,边部(增生边)为重熔变质成因的黑锆石。岩浆锆石幔部的~(206)Pb/~(238)U年龄加权平均值为(500.6±2.6)Ma~(501.1±2.5)Ma,代表该片麻岩的早古生代岩浆结晶年龄。边部变质锆石的新生代重熔年龄为(37.7±0.5)Ma,可能代表藏南拆离系的启动时间。早古生代岩浆锆石幔部的ε_(Hf)(t)值为-2.1-+5.3 (平均值为+2.2),Hf同位素两阶段模式年龄(TDM2)为1.1~1.6 Ga(平均值为1.3 Ga),表明其源岩起源于高喜马拉雅元古宙地层的部分熔融。结合区域内早古生代岩浆活动和新生代穹隆构造变质事件,本文认为错那洞花岗质片麻岩的形成受控于早古生代原特提斯洋壳板片向冈瓦纳大陆下俯冲的造山作用,同时记录了新生代印度一欧亚大陆碰撞造山后的变质和深熔事件。 相似文献
7.
威海地区出露古元古代泥质麻粒岩,其构造属性仍存在争议.泥质麻粒岩以透镜体的形式出露在花岗质片麻岩中,透镜体从核部到边部的岩性逐渐变化:未变形的粗粒泥质麻粒岩、面理化的细粒泥质麻粒岩、石榴黑云片麻岩和混合岩化麻粒岩.粗粒泥质麻粒岩,粗粒斑状变晶结构,块状构造;细粒泥质麻粒岩,细粒斑状变晶结构,面理发育;石榴黑云片麻岩,斑状变晶结构,片麻状构造,上述3种岩石的主要矿物组合均为石榴子石+黑云母+斜长石(反条纹长石)+石英+矽线石;混合岩,条带状构造,暗色残余体主要矿物组合为石榴子石+斜长石+黑云母+石英+矽线石,浅色体矿物组合为石英+斜长石+钾长石.所有样品均有金红石、锆石和独居石等副矿物.粗粒泥质麻粒岩中的锆石颗粒均为浑圆近等粒,具有典型的麻粒岩相变质锆石的特征:锆石CL图像为均一的云雾状或补丁状结构,低的Th/U比值(0.01~0.30),强烈的Ce正异常和Eu负异常,HREE的亏损及高的Hf/Y比值(19~537).利用锆石Ti温度计获得的变质温度为788~892℃(加权平均值为837±24℃).锆石U-Pb定年获得上交点年龄为1 863±18 Ma,206Pb/238U加权平均年龄为1 832±23 Ma.εHf(t)值为-3.4~-4.9(加权平均值为-4.23±0.35),相应的两阶段模式年龄(TDM2)为2 716±107 Ma~2 807±93 Ma(加权平均值为2 767±44 Ma).细粒泥质麻粒岩中的锆石也具有麻粒岩相锆石的CL和微量元素特征,Ti含量温度计获得的变质温度为804~909℃(加权平均值为845±23℃),锆石U-Pb上交点年龄为1 823±14 Ma,谐和206Pb/238U年龄加权平均值为1 812±13 Ma,εHf(t)为-3.7~-5.7(加权平均值为-4.67±0.37),TDM2为2 705±133 Ma~2 826±116 Ma(加权平均值为2 766±46 Ma).石榴黑云片麻岩中的锆石也具有麻粒岩相变质锆石的CL和微量元素特征,锆石Ti含量计算变质温度为785~923℃(加权平均值为820±32℃),锆石U-Pb上交点年龄为1 807±22 Ma,εHf(t)为-4.5~-9.0(加权平均值为-6.07±0.48),TDM2为2 742±90 Ma~3 020±92 Ma(加权平均值为2 839±41 Ma).混合岩中的锆石大部分具有核-边结构.根据Ti含量温度计获得的混合岩中麻粒岩相变质锆石核的变质温度为754~875℃(加权平均值为818±30℃),U-Pb上交点年龄为1 822±19 Ma,εHf(t)值为-4.3~-6.3(加权平均值为-5.47±0.35),TDM2为2 742±82 Ma~2 864±91 Ma(加权平均值为2 814±43 Ma).可见,麻粒岩、石榴黑云片麻岩和混合岩经历了相同的麻粒岩相峰期变质作用(~1.8 Ga),具有相同的原岩属性,即晚太古代(2.7~2.8 Ga)的地壳物质.麻粒岩透镜体从核部到边部岩性的变化,可能受到晚三叠纪碰撞造山作用的不同程度改造.因此,威海超高压地体中出露的泥质麻粒岩透镜体,在构造亲属性上可能属于华北克拉通地壳物质,成因上可能与哥伦比亚超大陆的演化有关,在三叠纪大陆俯冲碰撞过程中卷入造山带. 相似文献
8.
西昆仑的深变质岩类主要发育于布伦阔勒岩群之中,其中的高压麻粒岩是西昆仑造山带中目前已知的变质程度最高的岩石。本文以其中的泥质高压麻粒岩为研究对象,结合岩相学、相平衡模拟以及锆石年代学分析等方法进行研究。结果显示其峰期变质矿物组合蓝晶石+石榴石+钾长石,是典型的泥质高压麻粒岩岩石组合。根据相平衡模拟估算,高压麻粒岩相峰期变质的温压条件高于850℃及1.4GPa,退变质的温压条件约为650℃和0.6GPa。SHRIMP U-Pb锆石定年结果显示泥质高压麻粒岩记录了两期变质,第一期暗色变质锆石年龄为ca.185Ma,代表岩石从高压麻粒岩相峰期变质退变至近固相线阶段的年龄;第二期亮色变质增生边年龄为ca.166Ma,代表后期退变质年龄;而高压麻粒岩相峰期变质时代应在200~185Ma之间。高压麻粒岩的变质条件、顺时针的P-T轨迹及锆石年代学的结果指示了晚三叠世-早侏罗世的碰撞造山事件(ca.200~166Ma)。结合区域地质资料,推断在西昆仑山内存在一条中生代的中-高压变质带,这条变质带代表了古特提斯洋关闭塔里木与羌塘地块碰撞拼合的位置。 相似文献
9.
东喜马拉雅构造结南迦巴瓦群高压麻粒岩中含石榴石花岗岩脉锆石SHRIMP U-Pb定年及其与折返作用 总被引:13,自引:10,他引:3
东喜马拉雅构造结核部的南迦巴瓦群是经历了高压麻粒岩相峰期变质、角闪岩相退变质和强烈混合岩化作用形成的以含有高压麻粒岩透镜体或夹层为特色的变质岩组合。地质地球化学研究表明产于退变质高压麻粒岩中的含石榴石花岗岩脉具有高钾、富铝、轻稀土强烈富集、分馏程度很高、重稀土相对亏损、Eu强烈亏损、大离子亲石元素及放射性元素相对原始地幔值强烈富集、Rb/Sr1.4的特征。利用花岗岩的主要成分及锆的含量估算的岩浆初始温度为792~801℃,略低于南迦巴瓦群的峰期变质温度850℃。锆石SHRIMPU-Pb定年结果显示锆石核部年龄集中在519~525Ma之间,揭示出印度地块经历泛非期构造运动改造的痕迹。锆石边部主要存在39~44Ma、24~25Ma和7.3Ma三个年龄段,前者代表了花岗岩浆的侵位时代,第二个年龄段是对MCT和STDS构造热事件改造的反映,后者揭示出构造-浅表反馈作用的信息。说明含石榴石花岗岩脉是在南迦巴瓦群折返过程中近等温降压条件下地壳岩石发生"干"深熔作用形成的高钾过铝质钙碱性花岗岩,以及南迦巴瓦群在经历峰期变质作用后很快就开始折返,并在后碰撞过程中经历了藏南拆离系(STDS)和主中央冲断带(MCT)构造事件及后期构造-浅表反馈作用的影响。 相似文献
10.
西藏南部南迦巴瓦地区中新世-上新世地壳深熔作用 总被引:1,自引:0,他引:1
位于喜马拉雅东构造结的南迦巴瓦地块经历了复杂的构造变形、强烈的变质和深熔作用,是研究碰撞造山过程中地壳深熔作用的重要对象。完整地厘定新生代晚期岩浆作用期次对于揭示南迦巴瓦地区的构造演化历史和深部过程具有重要意义。南迦巴瓦地块3件淡色花岗岩样品的锆石U-Pb定年结果显示该地块经历了11.30±0.16Ma和2.59±0.04Ma两期地壳深熔作用,可能与南迦巴瓦地块晚新生代快速隆升和剥蚀相关。南迦巴瓦地块保存了大量的~11Ma变质作用和地壳深熔作用记录指示该时间段为构造活动剧烈期。上新世晚期的淡色花岗岩表明,穹窿的隆升和剥蚀所导致的岩浆作用至少持续到了~2.59Ma,代表了南迦巴瓦地区一次年轻的构造岩浆事件。 相似文献
11.
Monazite behaviour during isothermal decompression in pelitic granulites: a case study from Dinggye,Tibetan Himalaya 总被引:1,自引:0,他引:1
Monazite is a key accessory mineral for metamorphic geochronology, but interpretation of its complex chemical and age zoning acquired during high-temperature metamorphism and anatexis remains a challenge. We investigate the petrology, pressure–temperature and timing of metamorphism in pelitic and psammitic granulites that contain monazite from the Greater Himalayan Crystalline Complex (GHC) in Dinggye, southern Tibet. These rocks underwent isothermal decompression from pressure of >10 kbar to ~5 kbar at temperatures of 750–830 °C, and recorded three metamorphic stages at kyanite (M1), sillimanite (M2) and cordierite-spinel grade (M3). Monazite and zircon crystals were dated by microbeam techniques either as grain separates or in thin sections. U–Th–Pb ages are linked to specific conditions of mineral growth on the basis of zoning patterns, trace element signatures, index mineral inclusions (melt inclusions, sillimanite and K-feldspar) in dated domains and textural relationships with co-existing minerals. The results show that inherited domains (500–400 Ma) are preserved in monazite even at granulite-facies conditions. Few monazites or zircon yield ages related to the M1-stage (~30–29 Ma), possibly corresponding to prograde melting by muscovite dehydration. During the early stage of isothermal decompression, inherited or prograde monazites in most samples were dissolved in the melt produced by biotite dehydration-melting. Most monazite grains crystallized from melt toward the end of decompression (M3-stage, 21–19 Ma) and are chemically related to garnet breakdown reactions. Another peak of monazite growth occurred at final melt crystallization (~15 Ma), and these monazite grains are unzoned and are homogeneous in composition. In a regional context, our pressure–temperature–time data constrains peak high-pressure metamorphism within the GHC to ~30–29 Ma in Dinggye Himalaya. Our results are in line with a melt-assisted exhumation of the GHC rocks. 相似文献
12.
采用激光拉曼技术,配备电子探针和阴极发光测试,确认苏鲁地体大多数花岗质片麻岩,所有类型片麻岩、斜长角闪岩、蓝晶石英岩和大理岩的锆石中均隐藏以柯石英为代表的超高压包体矿物组合。其中花岗质片麻岩典型超高压包体矿物为柯石英±多硅白云母;副片麻岩为柯石英+石榴子石+绿辉石、柯石英±石榴子石+硬玉+多硅白云母+磷灰石、柯石英+多硅白云母±磷灰石;斜长角闪岩为柯石英+石榴子石+绿辉石±金红石;蓝晶石英岩为柯石英+蓝晶石+金红石+磷灰石、柯石英+蓝晶石+多硅白云母+金红石;大理岩为柯石英+透辉石、柯石英+橄榄石。表明苏鲁地体由榴辉岩及其围岩所组成的巨量陆壳物质曾普遍发生深俯冲,并经历了超高压变质作用。锆石的矿物包体分布特征及相应的阴极发光图像研究表明,在同一样品中,锆石的成因特征存在明显差异。有的锆石显示继承性(碎屑)锆石的核(core)、超高压变质的幔(mantle)和退变质的边(rim);有的锆石则具有超高压的核、幔和退变质的边;而有的锆石却记录了深俯冲的核、超高压的幔和退变质的边。标志着苏鲁超高压变质带各类岩石副矿物锆石均具有十分复杂的结晶生长演化历史。因此,在充分研究锆石中矿物包体性质、分布特征以及相应阴极发光图像的基础上,采用SHRIMP离子探针技术,在锆石晶体的不同 相似文献
13.
Three monazite generations were observed in garnet-bearing micaschists from the Schobergruppe in the basement to the south of the Tauern Window, Eastern Alps. Low-Y monazite of Variscan age (321?±?14?Ma) and high-Y monazite of Permian age (261?±?18?Ma) are abundant in the mica-rich rock matrix and in the outer domains of large garnet crystals. Pre-Alpine monazite commonly occurs as polyphase grains with low-Y Variscan cores and high-Y Permian rims. Monazite of Eo-Alpine age (112?±?22?Ma) is rarer and was observed as small, partly Y-enriched grains (3?wt. %?Y2O3) in the rock matrix and within garnet. Based on monazite-xenotime thermometry, Y?+?HREE values in monazite indicate minimum crystallization conditions of 500?°C during the Variscan and 650?°C for the Permian and Alpine events, respectively. Garnet zoning and thermobarometric calculations with THERMOCALC 3.21 record an amphibolite facies, high-pressure stage of ~600?°C/13?C16?kbar, followed by a thermal maximum at 650?C700?°C and 6?C9?kbar. The Eo-Alpine age for these two events is supported by inclusions of Cretaceous monazite in the garnet domains used for thermobarometric constraints and through the high growth temperatures of Eo-Alpine monazite, which is consistent with that of the thermal maximum (~700?°C). The age and growth conditions of a few Mn-rich garnet cores, sporadically present within Eo-Alpine garnet, are unclear because inclusions of monazite, plagioclase and biotite necessary for thermobarometric- and age constraints are absent. However, based on monazite thermometry, Permian and Variscan metamorphic conditions were high enough for the growth of pre-Alpine garnet. The formation of Variscan garnet and its later resorption, plus Y-release, would also explain the high Y in Permian monazite, which cannot originate from preexisting Variscan monazite only. Monazite of Variscan, Permian and/or Eo-Alpine ages were also observed in other garnet-bearing micaschists from the Schobergruppe. This suggests that the basement of the Schobergruppe was overprinted by three discrete metamorphic events at conditions of at least lower amphibolite facies. While the Variscan event affected all parts of this basement, the younger events are more pronounced in its structurally lower units. 相似文献
14.
中国大陆科学钻探主孔0~4500米变质岩石锆石中保存的超高压矿物包体 总被引:14,自引:9,他引:14
中国大陆科学钻探主孔0-4500米的岩心主要由榴辉岩、斜长角闪岩、副片麻岩、正片麻岩以及少量的超基性岩所组成。岩相学研究结果表明,榴辉岩的围岩普遍经历了强烈角闪岩相退变质作用的改造,峰期超高压变质的矿物组合已完全被后期退变质过程中角闪岩相矿物组合所替代。采用激光拉曼技术,配备电子探针和阴极发光测试,发现主孔224件岩心中有121件(包括榴辉岩、斜长角闪岩、副片麻岩和正片麻岩)样品的锆石中普遍隐藏以柯石英为代表的超高压矿物包体,且不同岩石类型锆石中所保存的超高压矿物包体组合存在明显差异。(含多硅白云母)金红石石英榴辉岩锆石中保存的典型超高压包体矿物组合为柯石英 石榴石、柯石英 石榴石 绿辉石 金红石和柯石英 多硅白云母 磷灰石。黑云绿帘斜长角闪岩锆石中保存的超高压矿物组合为柯石英 石榴石 绿辉石、柯石英 石榴石 多硅白云母和柯石英 绿辉石 金红石,与榴辉岩所保存的超高压矿物组合十分相似,表明该类斜长角闪岩是由超高压榴辉岩在构造折返过程中退变质而成。在副片麻岩类岩石,如石榴绿帘黑云二长片麻岩锆石中,代表性的超高压包体矿物组合为柯石英 多硅白云母和柯石英 石榴石等;而在石榴黑云角闪钠长片麻岩锆石中,则保存柯石英 硬玉 石榴石 磷灰石、柯石英 硬玉 多硅白云母 磷灰石和柯石英 石榴石 磷灰石等超高压矿物包体。在正片麻岩锆石中,标志性的超高压矿物包体为柯石英、柯石英 多硅白云母、柯石英 蓝晶石 磷灰石和柯石英 蓝晶石 榍石等。此外,在南苏鲁东海至临沭一带的地表露头以及一系列卫星孔岩心的锆石中,也普遍发现以柯石英为代表的标志性超高压矿物包体,表明在南苏鲁地区由榴辉岩及其围岩的原岩所组成的巨量陆壳物质(方圆>5000km2,厚度超过4.5km)曾整体发生深俯冲,并经历了超高压变质作用。该项研究对于重塑苏鲁-大别超高压变质带俯冲-折返的动力学模式有着重要的科学意义。 相似文献
15.
点苍山-哀牢山杂岩带多期变质作用:嘎洒地区变沉积岩锆石微量元素与U-Pb年代学制约 总被引:2,自引:2,他引:0
点苍山-哀牢山杂岩带位于青藏高原东南缘,为云南三江地区一条重要的造山带,由扬子板块和印支板块于晚二叠世-中晚三叠世碰撞拼合而成。杂岩带主要由各类副片麻岩、片岩、石英岩、大理岩和斜长角闪岩构成,岩石发育强烈糜棱岩化和深熔作用。本文选取哀牢山北段新平嘎洒地区变沉积岩为研究对象,通过对变沉积岩锆石的阴极发光图像、微量元素、矿物包裹体组合、表面形态和U-Pb年龄的综合研究,揭示出嘎洒地区哀牢山杂岩经历了两期变质事件:其中,含石榴子石斜长二云母片岩中30颗变质锆石获得了较为一致的206Pb/238U年龄215±6Ma~227±5Ma,加权平均年龄为222.3±1.2Ma(n=30,MSWD=0.27),这些锆石具有浑圆状或椭圆状形态、较为均匀的阴极发光图像、平坦的HREE配分模式((Lu/Gd)N=0.73~4.08)和弱的负Eu异常,这些特征与典型的高级变质岩中变质锆石相似,而锆石的Th/U比值较为分散为0.06~0.84,平均值为0.45,可能与变质过程中富Th矿物独居石分解有关。变质年龄与杂岩带中点苍山和元阳地区变质岩中、晚三叠世变质年龄极为吻合,指示这期变质事件与中-晚三叠世古特提斯洋闭合-造山有关,标志着点苍山-哀牢山杂岩带为三江地区一条重要的古缝合线。此外,嘎洒地区夕线石榴黑云二长片麻岩的岩相学特征显示,岩石经历了石榴子石的转熔作用,除两颗锆石年龄为35.4Ma外,28颗锆石(增生边)给出了误差范围内较为一致的206Pb/238U年龄(27.3±0.5Ma~31.9±0.5Ma),加权平均年龄为29.4±0.53Ma(n=28,MSWD=2.0)。这些锆石的增生边中的矿物包裹体组合为夕线石+钾长石+黑云母+石英+独居石,且具有较低的Th/U比值(0.01~0.1),平坦的重稀土(HREE)配分模式((Lu/Gd)N=0.45~7.59)和中等程度的负Eu异常,这些特征指示该类锆石为典型的变质锆石。变质年龄与新生代红河-哀牢山剪切带内大量发现的同剪切岩浆岩、变质岩的年龄较为一致,指示这期年轻的变质事件与岩石圈尺度大规模剪切运动有关。此外,两类变沉积岩中6颗继承性碎屑锆石的年龄分布范围为528~783Ma,这些锆石具有锥形的锆石形态,清晰的振荡环带,表面发育蚀痕和凹坑,较高的Th/U比(0.1),陡倾的HREE配分曲线,表明这些锆石为经过剥蚀-搬运-沉积的岩浆锆石,具有继承性碎屑锆石的特征,说明哀牢山杂岩变沉积岩中至少应包含新元古代和早古生代的沉积物源,指示研究区哀牢山杂岩带部分岩石并不属于真正意义上的扬子结晶基底。 相似文献
16.
A combined geochronological, geochemical, and Nd isotopic study of felsic high-pressure granulites from the Snowbird Tectonic Zone, northern Saskatchewan, Canada, has been carried out through the application of integrated electron microprobe and isotope dilution thermal ionization mass spectrometry (ID-TIMS) techniques. The terrane investigated is a 400 km2 domain of garnet–kyanite–K–feldspar-bearing quartzofeldspathic gneisses. Monazite in these granulites preserves a complex growth history from 2.6 to 1.9 Ga, with well-armored, high Y and Th grains included in garnet yielding the oldest U–Pb dates at 2.62 to 2.59 Ga. In contrast, matrix grains and inclusions in garnet rims that are not well-armored are depleted in Y and Th, and display more complicated U–Pb systematics with multiple age domains ranging from 2.5 to 2.0 Ga. 1.9 Ga monazite occurs exclusively as matrix grains. Zircon is typically younger (2.58 to 2.55 Ga) than the oldest monazite. Sm–Nd isotope analysis of single monazite grains and whole rock samples indicate that inclusions of Archean monazite in garnet are similar in isotopic composition to the whole rock signature with a limited range of slightly negative initial Nd. In contrast, grains that contain a Paleoproterozoic component show more positive initial Nd, most simply interpreted as reflecting derivation from a source involving consumption of garnet and general depletion of HREE's. Our preferred interpretation is that the oldest monazite dates record igneous crystallization of the protolith. The ca. 2.55 Ga dates in zircon and monazite record an extensive melting event during which garnet and ternary feldspar formed. Very high-pressure (> 1.5 GPa) metamorphism during the Paleoproterozoic at 1.9 Ga produced kyanite from garnet breakdown, and resulted in limited growth of new monazite and zircon. In the case of monazite, this is likely due to the armoring and sequestration of early-formed monazite such that it could not participate in metamorphic reactions during the high-pressure event, as well as the depletion of the REE's due to melt loss following the early melting event. 相似文献
17.
Relating zircon and monazite domains to garnet growth zones: age and duration of granulite facies metamorphism in the Val Malenco lower crust 总被引:14,自引:3,他引:14
Zircon from a lower crustal metapelitic granulite (Val Malenco, N‐Italy) display inherited cores, and three metamorphic overgrowths with ages of 281 ± 2, 269 ± 3 and 258 ± 4 Ma. Using mineral inclusions in zircon and garnet and their rare earth element characteristics it is possible to relate the ages to distinct stages of granulite facies metamorphism. The first zircon overgrowth formed during prograde fluid‐absent partial melting of muscovite and biotite apparently caused by the intrusion of a Permian gabbro complex. The second metamorphic zircon grew after formation of peak garnet, during cooling from 850 °C to c. 700 °C. It crystallized from partial melts that were depleted in heavy rare earth elements because of previous, extensive garnet crystallization. A second stage of partial melting is documented in new growth of garnet and produced the third metamorphic zircon. The ages obtained indicate that the granulite facies metamorphism lasted for about 20 Myr and was related to two phases of partial melting producing strongly restitic metapelites. Monazite records three metamorphic stages at 279 ± 5, 270 ± 5 and 257 ± 4 Ma, indicating that formation ages can be obtained in monazite that underwent even granulite facies conditions. However, monazite displays less clear relationships between growth zones and mineral inclusions than zircon, hampering the correlation of age to metamorphism. To overcome this problem garnet–monazite trace element partitioning was determined for the first time, which can be used in future studies to relate monazite formation to garnet growth. 相似文献
18.
吉南新太古代泥质片麻岩出露于龙岗岩群四道砬子河岩组中,本文通过系统的岩相学、矿物化学、激光拉曼和锆石U Pb同位素年代学等分析,研究其变质演化特点、变质作用时代及构造意义.结果表明:龙岗岩群四道砬子河岩组泥质片麻岩记录了3个变质演化阶段,其中峰前期进变质阶段(M1)的矿物组合为石榴石+黑云母+斜长石+石英+白云母;峰期变质阶段(M2)的矿物组合为石榴石+矽线石+钾长石+黑云母+斜长石+石英,达到麻粒岩相;峰后期退变质阶段(M3)以矽线石转变为蓝晶石为特征标
志,矿物组合为蓝晶石+石榴石+黑云母+斜长石+石英+白云母.变质矿物地质温压计限定其变质作用,峰前期(M1)T 为468~515 ℃,p 为(3.8~4.3)×105 kPa;峰期(M2)T 为703~760 ℃,p 为(6.6~7.1)×105kPa;峰后期(M3)T 为552~591℃,p 为(5.5~6.0)×105kPa;具有典型的近等压冷却型逆时针变质作用p T 演化轨迹特征,可能是在地幔柱与岩石圈相互作用的环境中变质作用与大量的幔源岩浆底侵作用有关.LA ICP MS锆石U Pb定年结果显示麻粒岩相变质作用时代为2495~2442Ma,属于新太古代变质热事件产物. 相似文献
19.
I. C. W. FITZSIMONS P. D. KINNY S. WETHERLEY D. A. HOLLINGSWORTH 《Journal of Metamorphic Geology》2005,23(4):261-277
Several petrographic studies have linked accessory monazite growth in pelitic schist to metamorphic reactions involving major rock‐forming minerals, but little attention has been paid to the control that bulk composition might have on these reactions. In this study we use chemographic projections and pseudosections to argue that discrepant monazite ages from the Mount Barren Group of the Albany–Fraser Orogen, Western Australia, reflect differing bulk compositions. A new Sensitive High‐mass Resolution Ion Microprobe (SHRIMP) U–Pb monazite age of 1027 ± 8 Ma for pelitic schist from the Mount Barren Group contrasts markedly with previously published SHRIMP U–Pb monazite and xenotime ages of c. 1200 Ma for the same area. All dated samples experienced identical metamorphic conditions, but preserve different mineral assemblages due to variable bulk composition. Monazite grains dated at c. 1200 Ma are from relatively magnesian rocks dominated by biotite, kyanite and/or staurolite, whilst c. 1027 Ma grains are from a ferroan rock dominated by garnet and staurolite. The latter monazite population is likely to have grown when staurolite was produced at the expense of garnet and chlorite, but this reaction was not intersected by more magnesian compositions, which are instead dominated by monazite that grew during an earlier, greenschist facies metamorphic event. These results imply that monazite ages from pelitic schist can vary depending on the bulk composition of the host rock. Samples containing both garnet and staurolite are the most likely to yield monazite ages that approximate the timing of peak metamorphism in amphibolite facies terranes. Samples too magnesian to ever grow garnet, or too iron‐rich to undergo garnet breakdown, are likely to yield older monazite, and the age difference can be significant in terranes with a polymetamorphic history. 相似文献