共查询到20条相似文献,搜索用时 343 毫秒
1.
柴北缘超高压变质带沙柳河蛇绿岩型地幔橄榄岩及其意义 总被引:8,自引:7,他引:8
本文报道了柴北缘大陆型超高压变质带沙柳河地区发现的蛇绿岩型地幔橄榄岩,其原始矿物组合为橄榄石 斜方辉石 铬铁矿。方辉橄榄岩中识别出两个世代的橄榄石,第一世代橄榄石(OI~1)残晶发育扭折带,化学成分与现代大洋地幔橄榄岩的橄榄石一致,第二世代橄榄石(OI~2)Fo 值高达94~97,其内部含有细小的流体包裹体,是第一世代橄榄石蛇纹石化后再次变质的产物。斜方辉石残晶的成分具有高 Al 和 Ca 的特征,与大洋地幔橄榄岩中斜方辉石的成分一致。温压条件的估算反映该橄榄岩体属于典型的尖晶石相方辉橄榄岩。其围岩是由堆晶辉长岩变质的条带状蓝晶石榴辉岩,二者构成了大洋蛇绿岩套的下部层位,并且与区内具有 N-MORB 和 OIB 性质的榴辉岩共生。这些特征表明该方辉橄榄岩应代表洋壳下伏地幔橄榄岩,从而揭示大陆造山带从早期的大洋俯冲消亡到大陆俯冲碰撞的完整过程。 相似文献
2.
大陆造山运动:从大洋俯冲到大陆俯冲、碰撞、折返的时限——以北祁连山、柴北缘为例 总被引:20,自引:8,他引:12
北祁连山和柴北缘是典型的早古生代大陆造山带,分别发育有北祁连山大洋型俯冲缝合带和柴北缘大陆型俯冲碰撞带.作为早古生代大洋冷俯冲的典型代表,北祁连山经历了从新元古代-寒武纪大洋扩张、奥陶纪俯冲和闭合及早泥盆世隆升造山的过程.高压变质岩变质年龄为490~440Ma,证明古祁连洋经历了至少50m.y.的俯冲过程.柴北缘超高压变质带是大陆深俯冲的结果,岩石学、地球化学和同位素年代学表明,柴北缘超高压变质带中榴辉岩的原岩分别来自洋壳和陆壳两种环境.高压/超高压变质的蛇绿岩原岩的年龄为517±11Ma,与祁连山蛇绿岩年龄一致.榴辉岩早期的变质年龄为443~473Ma,与祁连山高压变质年龄一致,代表大洋地壳俯冲的时代,而柯石英片麻岩和石榴橄榄岩所限定的超高压变质时代为420~426Ma,代表大陆俯冲的年龄.从大洋俯冲结束到大陆俯冲最大深度的转换时间最少需要20m.y..自420Ma起,俯冲的大洋岩石圈与跟随俯冲的大陆岩石圈断离,大陆地壳开始折返,发生隆升和造山.北祁连山和柴北缘两个不同类型的高压-超高压变质带反映了早古生代从大洋俯冲到大陆俯冲、隆升折返的造山过程. 相似文献
3.
柴北缘超高压变质带:从大洋到大陆的深俯冲过程 总被引:5,自引:0,他引:5
柴北缘超高压变质带同我国大别- 苏鲁造山带类似,同属典型的大陆型俯冲碰撞带。柯石英在榴辉岩和片麻岩中均
有发现,且石榴橄榄岩锆石中含有金刚石。本文从岩石学、温压计算、地球化学和年代学四个方面,对此带中的鱼卡、绿
梁山、锡铁山和都兰4 个榴辉岩和石榴橄榄岩出露地区近些年的研究进展进行了系统详细的综述。与典型的大陆型俯冲碰
撞带不同,柴北缘超高压变质带保存了早期陆壳俯冲前发生的洋壳深俯冲的证据。因此,结合现有数据,本文对柴北缘超
高压变质带从大洋俯冲到大陆俯冲碰撞的构造演化模式进行了探讨。 相似文献
4.
青藏高原北缘早古生代板块构造演化和大陆深俯冲 总被引:16,自引:3,他引:16
青藏高原北缘北祁连山和柴达木盆地北缘分别发育有2类不同的高压和超高压变质带.北祁连山为典型的环太平洋型俯冲带,榴辉岩锆石的SHRIMP年龄为464 Ma±5 Ma.而柴北缘为典型的大陆俯冲型变质带,片麻岩锆石中的柯石英证明柴北缘是一超高压变质带.石榴橄榄岩中的超硅石榴子石和橄榄石中的钛铁矿等出溶反映其形成深度大于200 km.柴北缘榴辉岩的原岩具有MORB和OIB的特征,并与北祁连山榴辉岩的年龄相同,代表早古生代祁连洋俯冲变质的时代.而含柯石英片麻岩的锆石和石榴橄榄岩超高压变质年龄均为423 Ma,代表大陆地壳深俯冲发生的时间.北祁连山和柴北缘很可能是一个俯冲带从大洋俯冲到大陆碰撞的不同阶段的产物. 相似文献
5.
中国大陆科学钻探主孔100~2000米超高压变质岩岩相学特征与变质变形史 总被引:13,自引:14,他引:13
中国大陆科学钻探工程的实施,为超高压变质带的研究打开了新的生面,加深了对苏鲁超高压变质带的认识。从100~2000米获得的岩心的岩石学观察,得知主要岩石类型有:(1)榴辉岩及石榴辉石岩;(2)榴辉岩质片麻岩;(3)石榴橄榄岩;(4)黑云(角闪)二长片麻岩和(5)碎裂岩等。榴辉岩可分幔源和壳源两类,壳源榴辉岩在钻孔中分布较广,上部最为集中;幔源榴辉岩,包括石榴辉石岩,在空间上与超镁铁岩有密切共生关系。榴辉岩质的片麻岩是一种中酸性的超高压岩石,与壳源的榴辉岩共生,显微镜下可以追索出它们之间的结构演化关系。石榴橄榄岩以石榴单辉橄榄岩为主,是俯冲带上部地幔楔加入于俯冲板片变质而成。石榴橄榄岩中的石榴子石富镁,单斜辉石为绿辉石并常含钛斜硅镁石,说明其经过超高压变质的过程。从变质岩石的组合,面理和线理产状的差异,地震反射面和构造角砾岩带的发育,发现以1600米为界,可大致分为2个岩片。上部岩片中多金红石榴辉岩而且出现频率很高,下部岩片中多为多硅白云母榴辉岩出现频率较低。由于隆升进入中下地壳,超高压变质岩普遍发生退变质。榴辉岩的早期退变质成为具后成合晶结构的石榴角闪岩,榴辉岩质片麻岩退变质形成绿帘黑云(角闪)斜长片麻岩,变质条件为角闪岩相,它可以部分熔融或受到钾交代作用而转变为黑云角闪二长片麻岩。后期的伸展造成了局部碎裂和角砾岩带,新生矿物为绿泥石,方解石和赤铁矿、绿帘石等,属绿帘角闪岩相和绿片岩相。主孔100~2000米的超高压变质岩石组合的确定,进一步说明了巨量的地壳物质可以深俯冲进入地幔并迅速折返;超高压变质岩石记录了陆壳俯冲折返和壳幔相互作用的过程,它们是板块下覆构造和地幔动力学的信息载体。 相似文献
6.
两条不同类型的HP/LT和UHP变质带对祁连-阿尔金早古生代造山作用的制约 总被引:13,自引:9,他引:4
在祁连-阿尔金造山带的南北两侧,分别出露有北祁连-北阿尔金HP/LT变质带和柴北缘-南阿尔金UHP变质带。北祁连-北阿尔金HP/LT变质带主要由蓝片岩、低温榴辉岩和高压变沉积岩所组成,榴辉岩形成的温压条件为420~570℃和2.0~2.5GPa,形成时代为510~440Ma。含硬柱石榴辉岩和含纤柱石高压变沉积岩的存在显示洋壳俯冲把大量水带到地幔深处。与HP/LT变质带伴生的早古生代蛇绿岩、俯冲增生杂岩、岛弧、弧后盆地等显示北祁连-北阿尔金为典型的早古生代增生造山带。柴北缘-南阿尔金UHP变质带由榴辉岩、石榴橄榄岩、高压麻粒岩及具有陆壳性质的正副片麻岩所组成,它们遭受了超高压变质作用(T700℃,P2.8GPa),UHP变质时代为500~420Ma,榴辉岩的原岩时代为750~850Ma,形成于新元古代的大陆裂谷环境。野外地质关系、岩石学及年代学研究显示柴北缘-南阿尔金HP-UHP变质带为大陆深俯冲作用的产物。在柴北缘-南阿尔金UHP变质带中,超高压榴辉岩和高压麻粒岩同时形成在不同的构造热环境中,构成大陆俯冲及碰撞造山带中的"双变质带",同时也显示柴北缘-南阿尔金造山带具有典型碰撞造山带的特征。祁连-阿尔金造山带南北两侧几乎同时发生增生造山作用和碰撞造山作用,构成由不同造山类型所组成的复合造山带。南北两侧的HP/LT变质带和UHP变质带以及可能存在的不同类型双变质带制约了祁连-阿尔金造山带早古生代的造山性质、造山类型以及造山机制。 相似文献
7.
南阿尔金-柴北缘高压-超高压变质带研究进展、问题及挑战 总被引:14,自引:0,他引:14
南阿尔金—柴北缘高压-超高压(HP/UHP)变质带为近10年来所新厘定,它分布在青藏高原北缘,延伸近1000km,被阿尔金断裂分成南阿尔金和柴北缘两部分,以含少量榴辉岩、石榴橄榄岩和含柯石英的片麻岩为特征。根据野外地质观察、岩石组合分析及其岩石学特征,可把南阿尔金—柴北缘HP/UHP变质带划分为6个HP/UHP变质单元,从西向东分别是:江尕勒萨依榴辉岩-片麻岩单元(JSU);巴什瓦克石榴橄榄岩-高压麻粒岩单元(BWU);鱼卡—落凤坡榴辉岩-片麻岩(片岩)单元(YLU);绿粱山石榴橄榄岩-高压麻粒岩单元(LLU);锡铁山榴辉岩-片麻岩单元(XTU);都兰榴辉岩-片麻岩单元(DLU)。研究显示,6个HP/UHP变质单元在岩石组合、形成的温度压力条件及变质演化历史等方面存在明显差异;榴辉岩相变质时代变化在420~500Ma之间,可能反映了早古生代沿南阿尔金—柴北缘HP/UHP变质带的多阶段或穿时性的俯冲作用。 相似文献
8.
硬柱石是大洋冷俯冲带的代表性矿物之一,富含水和Sr、Pb及稀土等微量元素,其形成和分解对于俯冲带流体活动、壳幔水和微量元素循环、地幔楔交代和熔融及岛弧岩浆作用等具有重要影响.但由于硬柱石对温度和压力的改变非常敏感,在板片折返过程中很容易分解,因此目前全球出露的硬柱石榴辉岩极为稀少.总结了榴辉岩中早期硬柱石存在的识别标志,并据此确定柴北缘超高压带西段鱼卡地区的含蓝晶石榴辉岩和斜黝帘石榴辉岩是峰期硬柱石榴辉岩退变质改造的结果.该发现说明柴北缘成为继大别造山带之后全球第二例出露硬柱石榴辉岩的大陆俯冲型造山带.利用相平衡计算方法恢复了这两种榴辉岩的变质演化过程,其中含蓝晶石榴辉岩的P-T轨迹和峰期变质条件均与区内大陆俯冲型含柯石英多硅白云母榴辉岩相似,而斜黝帘石榴辉岩峰期变质温压则略低.锆石定年获得含蓝晶石榴辉岩和斜黝帘石榴辉岩的变质时代分别为437 Ma和436 Ma,与带内已有超高压榴辉岩相变质时代相同,同时获得含蓝晶石榴辉岩的原岩结晶时代为1 273 Ma.相似的变质P-T轨迹和变质时代表明含蓝晶石榴辉岩与同剖面含柯石英多硅白云母榴辉岩共同经历了大陆深俯冲作用.这一结果表明,硬柱石榴辉岩并非大洋冷俯冲带特有,决定榴辉岩中是否出现硬柱石的主要因素是原岩成分和变质条件.在鱼卡地区,榴辉岩的矿物组合中能否出现硬柱石的最主要控制因素是原岩中的Mg含量,由高Mg#的基性岩变质形成的榴辉岩峰期矿物组合中易出现硬柱石. 相似文献
9.
本文提出一种对于造山带石榴橄榄岩的简单概念分类模型。该模型将造山带石榴橄榄岩划分为地幔楔型和俯冲带型两种类型,根据所记录温压条件及P-T轨迹的差异,地幔楔型石榴橄榄岩进而被划分为A-D四个亚类,分别对应不同厚度的克拉通型岩石圈地幔及普通大陆岩石圈地幔环境中冷的/古老的/稳定的地幔环境及与之对应的相对热的/年轻的/活动地幔环境。我们选择研究程度较高的斯堪的纳维亚加里东期造山带及我国柴北缘造山带中出露的石榴橄榄岩来检验该模型的适用性。出露于挪威西片麻岩地区的Mg-Cr型及Fe-Ti型石榴橄榄岩分别属于地幔楔型的A亚类(来自于古老的/冷的/厚的/亏损的克拉通岩石圈地幔)及壳源俯冲带石榴橄榄岩,而来自Seve,Troms和Linds地体的石榴橄榄岩则属于地幔楔型的C亚类(来自于古老的/冷的/薄的/亏损的大陆岩石圈地幔)后经历俯冲过程变为俯冲带石榴橄榄岩。对我国柴北缘超高压带绿梁山石榴橄榄岩的检验结果相对复杂。前人的研究表明绿梁山石榴橄榄岩存在三种不同的成因方式,对应分类模型中的:1)D亚类橄榄岩(阿拉斯加型岩浆岩堆晶体);2)壳源俯冲带型石榴橄榄岩;3)A亚类来自克拉通岩石圈地幔的太古代石榴橄榄岩。检验结果表明,该分类模型能较好的解释斯堪的纳维亚加里东期造山带中的石榴橄榄岩的出露规律,岩石学及矿物学特征及不同期次矿物之间的年代学关系,但对于我国绿梁山石榴橄榄岩的成因分类仍需进一步研究。假设该分类模型能适用于大多研究程度较高的造山带石榴橄榄岩,起到决定性作用的两个分类参数为地幔楔形成初期的平均温度(T)及造山带岩石圈地幔的厚度(P)。熔融作用发生的时间及深度同样是区分不同类型石榴橄榄岩的重要因素。 相似文献
10.
苏北东海超镁铁岩分为南、北两带。北带以变质橄榄岩为主,南带以洋壳堆积超镁铁岩为主,是“肢解的蛇绿岩”。推测蛇绿岩形成于中—新元古代扬子古大陆板块北缘苏北—胶南地体与胶北地体间的洋盆环境。变质橄榄岩为高温超高压下原始地幔岩经中等程度熔融后的残余地幔橄榄岩。堆积超镁铁岩是原始地幔岩部分熔融或岩浆结晶分离的产物,富含石榴石,与榴辉岩块伴生,是在中—新元古代由洋壳向南俯冲消减过程中形成的相对低温超高压变质岩。它们遭受强烈破碎,被挤压到东海岩群下部不同构造层位中,成为东海俯冲带混杂岩中的深源岩块。 相似文献
11.
The main hole (MH), and pre-pilot holes PP1, and PP3 of the Chinese Continental Scientific Drilling Project (CCSD) penetrated three different garnet peridotite bodies in the Sulu ultrahigh pressure (UHP) metamorphic belt, which are 80 m, 120 m, and 430 m thick, respectively. The bodies occur as tectonic blocks hosted in eclogite (MH peridotite) and gneisses (PP1 and PP3 peridotites). The peridotites in the MH are garnet wehrlites, whose protoliths were ultramafic cumulates based on olivine compositions (Fo79-89) and other geochemical features. Zoned garnet and omphacite (with 4-5 wt.% Na2O) are typical metamorphic minerals in these rocks, and, along with P-T estimates based on mineral pairs, suggest that the rocks have undergone UHP metamorphism. SHRIMP U-Pb isotope dating of zircon from the garnet wehrlite yielded a Paleozoic protolith age (ca. 346-461 Ma), and a Mesozoic UHP metamorphic age (ca. 220-240 Ma). The peridotites in PP1 consist of interlayered garnet (Grt)-bearing and garnet-free (GF) peridotite. Both types of peridotite have depleted mantle compositions (Mg# = 90-92) and they display transitional geochemical features. The intercalated layers probably reflect variations in partial melting rather than pressure variations during metamorphism, and the garnets may have been formed by exsolution from orthopyroxene during exhumation. These peridotites were probably part of the mantle wedge above the subduction zone that produced the UHP metamorphism and thus belonged to the North China Block before its tectonic emplacement. The exhumation of the subducted Yangtze Block brought these mantle fragments to shallow crustal levels. The ultramafic rocks in PP3 are dominantly dunite with minor garnet dunite. Their high Mg# (92-93) and relatively uniform chemical compositions indicate that they are part of a depleted mantle sequence. The presence of garnet replacing spinel and enclosing pre-metamorphic minerals such as olivine, clinopyroxene and spinel suggests that these rocks have undergone progressive metamorphism. SHRIMP U-Pb isotope dating of zircon from these rocks yielded two age groups: 726 ± 56 Ma for relic magmatic zircon grains and 240 ± 2.7 Ma for the newly formed metamorphic zircon. The older group is similar in age to granitic intrusions within the Dabie-Sulu belt, suggesting that the PP3 garnet peridotite may record the early emplacement of the peridotite into the crust. The younger dates coincide with the age of UHP metamorphism during continent-continent collision between the Yangtze and North China Blocks, suggesting that these peridotites were subducted to depths equivalent to the coesite facies and later exhumed. Thus, the garnet peridotites in the CCSD cores include both ultramafic rocks that existed originally in the subducted plate and rocks from the mantle wedge above the subducted plate, i.e., part of the North China Block. 相似文献
12.
Early Palaeozoic North Qaidam UHP metamorphic belt on the north-eastern Tibetan plateau and a paired subduction model 总被引:8,自引:0,他引:8
Yang Jingsui Xu Zhiqin Zhang Jianxin Song Shuguang Wu Cailai Shi Rendeng Li Haibing Maurice Brunel 《地学学报》2002,14(5):397-404
ABSTRACT An Early Palaeozoic UHP metamorphic belt was recently discovered in the North Qaidam Mountains in the north-eastern part of the Tibet Plateau. The belt contains abundant eclogite with lesser amounts of garnet peridotite and gneiss. The paragneiss contains abundant zircon with coesite inclusions whereas the eclogite has garnet with coesite pseudomorphs and omphacite with exsolved quartz. The calculated peak metamorphic conditions for the eclogite are T = 730 °C and P = 2.8 GPa. The garnet peridotites are magnesium-rich with Mg#s [100 × Mg/(Mg + Fe)] up to 92. Olivine in the peridotites is highly magnesian (Fo > 91.5) and TiO2 -poor and is typical of low- T garnet peridotites. Calculated peak metamorphic conditions for the peridotites are T = 837 °C and P = 2.5 GPa. U–Pb and Sm–Nd isotope dating indicate that continental subduction started during the early Ordovician (∼ 495 Ma). The North Qaidam UHP, together with the North Qilian HP belt about 300 km to the north, constitute a pair of genetically related early Palaeozoic subduction zones along the northern margin of the Tibet Plateau. 相似文献
13.
Petrochemical constraints for dual origin of garnet peridotites from the Dabie-Sulu UHP terrane, eastern-central China 总被引:44,自引:3,他引:41
Garnet peridotites occur as lenses, blocks or layers within granulite–amphibolite facies gneiss in the Dabie-Sulu ultra-high-pressure (UHP) terrane and contain coesite-bearing eclogite. Two distinct types of garnet peridotite were identified based on mode of occurrence and petrochemical characteristics. Type A mantle-derived peridotites originated from either: (1) the mantle wedge above a subduction zone, (2) the footwall mantle of the subducted slab, or (3) were ancient mantle fragments emplaced at crustal depths prior to UHP metamorphism, whereas type B crustal peridotite and pyroxenite are a portion of mafic–ultramafic complexes that were intruded into the continental crust as magmas prior to subduction. Most type A peridotites were derived from a depleted mantle and exhibit petrochemical characteristics of mantle rocks; however, Sr and Nd isotope compositions of some peridotites have been modified by crustal contamination during subduction and/or exhumation. Type B peridotite and pyroxenite show cumulate structure, and some have experienced crustal metasomatism and contamination documented by high 87 Sr/86 Sr ratios (0.707–0.708), low εNd ( t ) values (−6 to −9) and low δ18 O values of minerals (+2.92 to +4.52). Garnet peridotites of both types experienced multi-stage recrystallization; some of them record prograde histories. High- P–T estimates (760–970 °C and 4.0–6.5±0.2 GPa) of peak metamorphism indicate that both mantle-derived and crustal ultramafic rocks were subducted to profound depths >100 km (the deepest may be ≥180–200 km) and experienced UHP metamorphism in a subduction zone with an extremely low geothermal gradient of <5 °C km−1 . 相似文献
14.
The Luliangshan garnet peridotite massif is an ultramafic complex in the North Qaidam UHPM belt, NW China. The strongly layered complex comprising garnet-bearing dunite, garnet-harzburgite, garnet-lherzolite and garnet-pyroxenite and garnet-free dunite, occurs together with eclogite embedded in various continental gneisses. The geological setting, the internal structure, bulk-composition, rare earth elements, isotopic and mineral composition data show that the garnet peridotite derives from a middle Ordovician Alaskan-type layered sub-arc cumulate intrusion of ascending mantle wedge melts. An abyssal peridotite protolith can be excluded. During the Ordovician-Silurian continental collision, thickening and foundering, the Luliangshan peridotite complex was exposed to ultrahigh pressures (UHP) reaching 5.5 GPa possibly >6 GPa at temperatures of 900 °C (perhaps up to 1000 °C) corresponding to a depth of ∼200 km. The extreme pressure conditions have been derived from thermobarometry using mineral compositions of the garnet peridotite assemblages, but they are supported by a wealth of decompression-induced mineral exsolutions in UHP minerals and by diamond inclusion in zircon. The Luliangshan garnet peridotite has experienced four stages of retrograde overprint during exhumation that lasted into the Devonian: (i) decompression-induced unmixing of the UHP minerals; (ii) garnet kelyphitisation; (iii) amphibole overprinting and (iv) serpentinization. Hydrous minerals occurring within peak metamorphic assemblage represent pseudo-inclusions, that is reaction products of reactions related to various stages of decompression and cooling rather than prograde inclusions during porphyroblast growth. 相似文献
15.
Ultrahigh-pressure garnet peridotites from the devolatilization of sea-floor hydrated ultramafic rocks 总被引:8,自引:0,他引:8
Garnet peridotites occur in quartzofeldspathic gneisses in the Northern Qaidam Mountains, western China. They are rich in Mg and Cr, with mineral compositions similar to those in mantle peridotites found in other orogenic belts and as xenoliths in kimberlite. Garnet‐bearing lherzolites interlayered with dunite display oriented ilmenite and chromite lamellae in olivine and pyroxene lamellae in garnet that have been interpreted to indicate pressures in excess of 6 GPa. However, some garnet porphyroblasts include hornblende, chlorite and spinel + orthopyroxene symplectite after garnet; some clinopyroxene porphyroblasts include abundant actinolite/edenite, calcite and lizardite in the lherzolite; some olivine porphyroblasts (Fo92) include an earlier generation Mg‐rich olivine (Fo95–99), F‐rich clinohumite, pyroxene, chromite, anthophyllite/cummingtonite, Cl‐rich lizardite, carbonates and a new type of brittle mica, here termed ‘Ca‐phlogopite’, in the associated dunite. The pyrope content of garnet increases from core to rim, reaching the pyrope content (72 mol.%) of garnet typically found in the xenoliths in kimberlite. The simplest interpretation of these observations is that the rock association was formerly mantle peridotite emplaced into the oceanic crust that was subjected to serpentinization by seawater‐derived fluids near the sea floor. Dehydration during subduction to 3.0–3.5 GPa and 700 °C transformed these serpentinites into garnet lherzolite and dunite, depending on their Al and Ca contents. Pseudosection modelling using thermocalc shows that dehydration of the serpentinites is progressive, and involved three stages for Al‐rich and two stages for Al‐poor serpentinites, corresponding to the breakdown of the key hydrous minerals. Static burial and exhumation make olivine a pressure vessel for the pre‐subduction mineral inclusions during ultrahigh‐pressure (UHP) metamorphism. The time span of the UHP event is constrained by the clear interface between the two generations of olivine to be very short, implying rapid subduction and exhumation. 相似文献
16.
中国东部上地幔岩石相转变及其意义 总被引:2,自引:0,他引:2
中国东部新生代玄武岩和大别-苏鲁超高压变质带中的含石榴石相橄榄岩, 带来了发生在上地幔的尖晶石→石榴石相转变和铝辉石→贫铝辉石+石榴石的重要信息, 为中国东部上地幔岩石结构分层奠定了重要基础.通过岩石学与实验岩石学的研究, 推导出发生相转变的P-T条件, 为建立中国东部大陆上地幔岩石分层结构提供了重要约束.尖晶石二辉橄榄岩向石榴石二辉橄榄岩相转变发生在55~70km, 随着深度增加, 石榴石二辉橄榄岩从富铝石榴石二辉橄榄岩(70~120km) 转变为贫铝石榴石二辉橄榄岩(> 120~150km). 相似文献
17.
造山带幔源(M型)橄榄岩虽然在高压/超高压变质带分布不多,但由于其来自俯冲板块上覆的岩石圈地幔,因此是研究俯冲隧道内俯冲板片与地幔楔之间相互作用的重要对象,对于还原超高压变质带的演化有重要意义.柴北缘鱼卡榴辉岩-片麻岩区边部附近的开屏沟存在一套橄榄岩,其岩石类型、成因、时代等都缺乏研究.对开屏沟橄榄岩全岩的主量和微量元素及铂族元素、橄榄石主量元素、锆石U-Pb年龄和Hf同位素进行了研究.结果显示,其全岩具有高的Mg#、Mg/Si和Ni值,同时表现出亏损难溶的HFSE和HREE,轻微富集LILE和LREE中与流体活动性相关的元素;橄榄石具有较高的Fo值(90.11~92.77)与NiO含量(0.32%~0.45%)、低的CaO含量(< 0.02%);PGEs的球粒陨石标准化配分模式与交代橄榄岩和残留橄榄岩近似;两组变质锆石年龄为459.5±3.6 Ma和417.5±2.7 Ma,对应的εHf(t)值为-0.71~9.45和-11.96~-1.20,分别反映了洋壳流体(或早期大陆俯冲板片流体)和陆壳流体交代的性质和时限.开屏沟橄榄岩来源于俯冲带上覆地幔楔,遭受了不同来源流体不同程度的交代作用而获得地壳特征,同时为柴北缘大洋俯冲到陆陆碰撞的构造演化提供了新证据. 相似文献
18.
A new ultrahigh-pressure (UHP) metamorphic terrane, the Marun-Keu eclogite–peridotite–gneiss complex was established in the Polar Urals (Russia). Owing to the P–T parameters of formation of garnet peridotites obtained for the first time, it was established that they experienced UHP metamorphism with a peak in the diamond stability field (39 kbar, 830oC) due to subduction of rocks of the Marun-Keu complex to the mantle (a depth of more than 100 km). Relics of plagioclase peridotites preserved in central parts of large peridotite bodies and petrochemical data are evidence that Marun-Key garnet peridotites cannot be of mantle origin. A basic-ultrabasic intrusion, which formed in the upper crust, can be considered as their protolith. Later, rocks of the massif plunged to the mantle along the subduction zone and metamorphosed under high-P to ultrahigh-P conditions.
相似文献19.
《International Geology Review》2012,54(9):799-815
Garnet peridotites and pyroxenites have been reported from 11 of the 15 or so high-pressure/ultrahigh-pressure (HP/UHP) terranes in Eurasia. Most of these ultramafic rocks are Mg-Cr types, derived from depleted upper mantle, but some are more Fe-rich and originated by crystallization in ultramafic-mafic igneous complexes. The peridotites are polymetamorphic, with HP/UHP garnet-bearing assemblages being followed by a succession of retrograde assemblages related to exhumation and cooling; some also contain evidence for a pre-HP/UHP stage, such as spinel inclusions in garnet or the presence of Ti-clinohumite. Equilibration conditions have been calculated from all available analyses of garnetiferous assemblages, by application of the olivine-garnet Fe-Mg exchange thermometer and the Alin-orthopyroxene barometer, resulting in two distinct P-T regimes for garnet peridotites—one at high P/T in the coesite and diamond fields, and another at low P/T in the vicinity of the spinel-to-garnet transition. Garnet peridotites are thought to have evolved in at least four different tectonothermal settings, including: (1) emplacement of peridotites into oceanic or continental crust, followed by transport of peridotites and associated crust to UHP conditions by a subducting plate; (2) transfer of peridotites from a mantle wedge to the crust of an underlying, subducting plate; (3) origination from upwelling asthenosphere that passed through a high-temperature spinel peridotite stage, followed by cooling into the garnet peridotite field; and (4) extraction of garnet peridotites from ancient subcontinental lithosphere, perhaps by deep-seated faulting within a continental plate. 相似文献
20.
柴北缘超高压带中锡铁山榴辉岩的变质时代 总被引:10,自引:8,他引:2
锡铁山地体位于柴北缘超高压变质带的中部, 是柴北缘超高压变质带的重要组成部分。该地体由花岗质片麻岩、泥质片麻岩和相对较少的榴辉岩透镜体组成。大部分榴辉岩都经历了不同程度的后生合晶和角闪岩相退化变质改造。虽然近年来进行了大量的锆石U-Pb年代学研究,但榴辉岩相高压-超高压变质的时代一直存在争议,并且以前对锡铁山榴辉岩相变质时代的认识一直与相邻的绿梁山、鱼卡和其东部的都兰等地区的超高压变质年龄有明显的冲突。本文通过锡铁山榴辉岩锆石U-Pb年代学的研究,获得榴辉岩相变质锆石的206Pb/238U加权平均年龄为433±3Ma,与鱼卡地区榴辉岩的形成年龄一致,代表大陆俯冲时期的高压-超高压变质年龄。该研究对进一步了解锡铁山榴辉岩地体的变质演化和大陆地壳深俯冲有重要意义。 相似文献