大陆俯冲带地壳深熔作用的记录:来自超高压变质岩中多相晶体包裹体的研究北大核心CSCD

大陆碰撞过程中会发生广泛的部分熔融现象,形成深熔熔体。深入认识深熔熔体的组成和演化是大陆俯冲带化学地球动力学的主要研究内容。在熔融过程中产生的熔体会被超高压岩石中的转熔矿物所捕获,最终以多相晶体包裹体(multiphase crystal inclusion,简称MCI)的形式保存下来。多相晶体包裹体通常具有典型的负晶形和爆裂纹,主要以硅酸盐和碳酸盐矿物为主含有少量的硫酸盐矿物。矿物学、岩石学和地球化学原位微区分析的研究结果表明,多相晶体包裹体是由岩石部分熔融产生的初始硅酸盐或/和碳酸盐初始熔体熔体结晶而成。在降压折返过程中,高压岩石中的含水矿物,如多硅白云母、钠云母和帘石等脱水引发部分熔融产生硅酸盐熔体,而碳酸盐熔体则由碳酸盐矿物部分熔融产生。富Na矿物如钠云母脱水熔融产生的包裹体具有相对较高的Na含量,而部分富K的包裹体主要由富K矿物如多硅白云母脱水熔融所产生。近年来随着微区原位技术的飞速发展,从矿物的形态结构到矿物地球化学组成的测定技术有了飞速发展,通过对超高压岩石中包裹的多相晶体的详细研究,可限定大陆碰撞造山过程中部分熔融的组成、时限和形成机制,对大陆深俯冲的构造热演化和折返机制有重要制约。     

超高压变质作用过程中的流体——来自苏鲁超高压变质岩岩石学、氧同位素和流体包裹体研究的限定

苏鲁造山带超高压变质岩岩石学、氧同位素、流体包裹体和名义上无水矿物的研究表明,流体-岩石相互作用在大陆地壳的俯冲与折返过程中起到多重的重要作用,并形成了复杂的流体演化过程：（1）大陆表壳岩通过与高纬度大气降水的交换作用被广泛水化,并获得了异常低的氧同位素成分;（2）在水化陆壳物质的俯冲过程中发生了一系列的进变质脱水反应,所释放的流体主要结合进了高压、超高压含水矿物和名义上无水超高压矿物;（3）在超高压变质过程中,以水为主的变质流体通过选择性的吸收使其盐度逐渐升高,并在峰期出现高密度、高盐度的H2O或CO2-H2O流体。有机质的分解反应在局部形成了以CO2、N2、CH4或它们的混合物为主要成分的变质流体;（4）名义上无水超高压矿物的结构水出溶是早期退变质流体的主要来源,并在局部富集形成了高压变质脉体;（5）透入性的中、低盐度水流体活动使超高压变质岩通过一系列的水化反应转变成角闪岩相变质岩;（6）沿韧性剪切带和脆性破碎带的强烈水流体活动为绿片岩相退变质作用和低压石英脉的形成提供了变质流体;（7）可变盐度的H2O或CO2-H2O流体是整个超高压变质岩形成与折返过程中的主要流体,但局部的流体．岩石相互作用形成了非极性的变质流体。     

韧性剪切带型金矿床矿物中熔融包裹体与矿床成因研究

在新疆乔尕山及广东河台韧性剪切带金矿床的含金石英脉及糜棱岩中首次发现熔融包裹体及流体一熔融包裹体，其均一化温度分别为780～960℃与600℃。用电子探针及扫描电镜能谱对熔融包裹体子矿物成分进行分析，通过56个熔融包裹体231个测点分析，鉴定出石英、白云母、黑云母、磁铁矿等十种子矿物，组成不同的矿物组合。子矿物常含Si、Al、Na、K、Au、Ag、Cu等元素。剪切带金矿床中熔融包裹体的发现为其成因研究提供了新依据，表明成矿与多阶段硅酸盐熔体及流体作用有关。     

安徽石马超高压变质地体构造演化的流体包裹体响应

安徽石马超高压变质地体经历 5次构造变形 ,其特征是由深层次挤压韧性变形到浅层次的伸展脆性变形。相应地发育有 5期流体 ,它们的演化规律为 :早期以硅酸盐熔体和流体熔融体为主 ,随后富CO2 流体占优势 ,后期H2 O溶液起主导作用。总体而言 ,从老到新流体均一温度和含盐度均由高变低。在构造作用和流体作用的共同推动下 ,石马超高压变质地体经历了复杂的演化过程 :洋壳俯冲 ,超高压榴辉岩形成与形变→陆壳碰撞 ,榴辉岩折返→地体构造分异 ,榴辉岩就位→地体均衡隆起 ,榴辉岩抬升→地体差异隆起 ,榴辉岩剥露。因此 ,流体作用在研究超高压变质地体中占有重要地位。流体直接影响超高压变质地体形成的物理化学环境 ,在分析其形成深度时 ,应充分考虑流体超压问题。总之 ,在超高压地体演化过程中 ,流体一直是积极推动其发展的最活跃的因素。     

大别超高压变质带流体包裹体的组台关系与演变

对大别超高压变质带主要构造单元各类地质体岩石中的流体包裹体进行了岩相学和相变温度的观察与测定。流体包裹体类型和成分特征显示，与超高压变质、早期退变质有关的流体成分主要属于盐—H2O体系，减压熔融释放的流体成分主要属于NaCl—CO2—H2O体系，脆性变形期间涉及的成分流体主要属于NaCl—H2O体系。由于超高压变质岩系的快速折返抬升造成的压力迅速降低等影响，各个事件中形成的流体包裹体都发生了程度不同的颈缩及爆裂等捕获后变化，其密度大都已不能反映捕获时的状态。超高压变质和退变质岩石中常常叠加了与不同流体事件有关的流体包裹体组合，因此，对群体制样获得的各种化学成分和同位素成分等数据所做的各种地质解释风险较大。     

中国大陆科学钻探（CCSD）主孔超高压变质岩副矿物锆石中的流体包裹体研究

中国大陆科学钻探工程主孔位于苏鲁超高压变质地体南部,钻孔穿过的超高压岩石主要有榴辉岩、正、副片麻岩、石榴橄榄岩、角闪岩,以及少量片岩和石英岩。锆石是超高压岩石中的常见副矿物,按成因可以分为原岩锆石、变质(增生)锆石和新生锆石。这三类锆石中普遍含有矿物包体和少量流体包裹体,它们记录了超高压岩石经历的进变质、超高压变质和退变质期间流体作用的信息。锆石中的流体包裹体具有以下特征:(1)原岩锆石核部常见原生H2O和H2O-CO2包裹体,H2O包裹体的组成和盐度变化较大;而沿原岩锆石裂隙有时还有次生H2O-CO2和(或)CO2包裹体;(2)在变质锆石或锆石的变质增生带(幔部或边部)仅偶尔发现与超高压矿物包体共生的H2O-CO2包裹体;(3)榴辉岩,特别是片麻岩可以含大量微粒新生锆石,其中偶尔可见低盐度的H2O±CO2包裹体;(4)锆石中流体包裹体的丰度与主岩氧同位素值存在一定相关性:即具有很低δ18O值的岩石所含锆石中流体包裹体特别丰富,而具有正常氧同位素组成的岩石中锆石很少或不合流体包裹体;结合原岩锆石、变质锆石和新生锆石中均有中低盐度的H2O和H2O-CO2包裹体存在,反映了在大陆深俯冲-折返过程中变质流体具有继承性。H2O和H2O-CO2包裹体的等容线全都从根据矿物温压计获得的变质峰期压力-温度区间下部通过,推测在进变质-超高压变质峰期捕获的流体包裹体随后受到了改造。在进变质-超高压变质和退变质期间变质流体的存在促进了原岩锆石不同程度地受到溶蚀、变质增生和变质锆石、新生锆石的形成。     

超高压变质流体的组成与演化：中国大陆科学钻探工程主孔岩心的流体包裹体研究

中国大陆科学钻探工程主孔位于大别-苏鲁超高压变质带东段的江苏东海县,孔深为5100m,其上部2050m钻遇的岩石主要为榴辉岩,其次是正、副片麻岩、石榴橄榄(辉石)岩以及少量片岩和石英岩。它们经历了超高压变质作用和随后的角闪岩相退变质作用。通过对上述各种岩石的详细流体包体观察和RAMAN光谱分析,发现了五种不同成分的流体包裹体:(1)中-低盐度水溶液包裹体(Ⅰ型),呈原生的孤立和小群存在于榴辉岩和片麻岩锆石的岩浆核和超高压变质边缘,或存在于绿辉石、黝帘石和被绿辉石包裹的方解石和石英中,偶尔呈出溶包裹体产于磷灰石中,而主要沿绿辉石、石榴石、蓝晶石、黝帘石和石英等矿物的穿颗粒裂隙分布;也呈孤立和小群产于切穿榴辉岩的方解石脉和片麻岩重结晶石榴石和绿帘石中;(2)CO2(±CH4)-H2O包裹体(Ⅱ型),存在于锆石的岩浆核和变质边缘,或沿石英裂隙分布;(3)含石盐±SiO2±CaCO3的复杂盐水包裹体(Ⅲ型),呈原生流体包裹体产在榴辉岩的绿辉石中,与石英出溶棒一起平行于绿辉石的C轴分布,或产在石榴辉石岩透辉石的晶内裂隙中;(4)富CO2包裹体(Ⅳ型),在榴辉岩的石英中随机分布;(5)单气相包裹体(Ⅴ型),沿各种矿物穿颗粒裂隙分布。流体包裹体产状及其与捕获时代关系表明,Ⅰ型和Ⅱ型包裹体可以出现在超高压变质岩原岩、峰期变质和退变质各阶段。Ⅲ型包裹体出现在超高压变质岩的早期减压退变质阶段。而Ⅳ型和Ⅴ型包裹体主要形成于角闪岩相及更晚的退变质阶段。本研究的主要认识是:(1)低盐度H2O和CO2流体在进变质、超高压变质和退变质作用各阶段均有存在,这表明在整个超高压变质演化过程中流体具有继承性。(2)超高压变质岩原岩和角闪岩相退变质岩中存在较丰富的流体包裹体,但在超高压峰期捕获的流体包裹体却很少见,这表明丰富的原岩流体或在超高压进变质过程中被排出岩石体系,或进入含水超高压矿物和结合进名义无水矿物。(3)复杂成分原生流体包裹体的发现证明在超高压变质峰期后的早期减压退变质阶段存在一种高盐度似熔体流体,名义上的无水矿物在超高压条件下可以保存相当量的流体,并在退变质过程中分离出来,产生流体-岩石相互作用。(4)角闪岩阶段的流体包裹体具有各种不同的化学组成,且在局部富集,推测可能有部分外部加入的流体。(5)流体包裹体类型、丰度和成分在不同岩石类型中和不同钻孔深度都存在明显差异,表明超高压变质作用过程中没有大规模的透入性流体活动。(6)根据超高压变质峰期包裹体等容线得到的压力值大大低于根据矿物温压计获得的近峰期变质压力,这表明包裹体的密度在捕获后发生了改变。这些改变是由于流体渗漏、部分爆裂和流体-岩石相互作用所引起。     

苏北青龙山超高压变质榴辉岩流体包裹体特征与流体演化

根据青龙山超高压变质榴辉岩中流体包裹体的化学成分、矿物中的分布特征将岩石中的流体包裹体分为五类,即富N2包裹体、高盐度(22.4-略大于23.2wt%NaCl)的NaCl CaCl2 H2O体系流体包裹体、中高盐度(12.6-16.0wt%NaCl)的含Mg2 或Fe2 的NaCl H2O体系流体包裹体、中等盐度(6.4-10.5wt%NaCl)水溶液包裹体和低盐度(3.3-0.2wt%NaCl)的水溶液包裹体。富N2包裹体形成于超高压变质峰期阶段,高盐度的流体包裹体形成于超高压变质岩折返早期固体出溶体出溶阶段,中高盐度的流体包裹体形成于高压变质重结晶作用阶段,中等盐度的流体包裹体形成于角闪岩相变质重结晶作用阶段,低盐度的流体包裹体形成于折返晚期的绿片岩退变质作用阶段。超高压变质峰期阶段和折返早期的高盐度流体和中高盐度的流体主要来自继承原岩中的流体(如含NH4 矿物分解或片麻岩原岩中的有机质分解,名义上无水矿物中羧基水的出溶),晚期角闪岩相退变质阶段的中等盐度的流体除名义上无水矿物中羟基水的出溶外还有外来流体的加入,绿片岩相退变质作用阶段的流体主要为外来流体。     

庐山星子群变质流体的包裹体研究

庐山星子群沉积变质岩中发育平行区域片理的石英脉和长英质脉体,这些脉体的石英晶体内富含原生的流体包裹体,包括低盐度的含液体ＣＯ２包裹体、液体包裹体、纯ＣＯ２包裹体和高盐度含子矿物包裹体。它们与中生代伟晶岩脉体中包裹体在均一温度、盐度和ＣＯ２密度等方面的明显差异和变质脉体中含液体ＣＯ２包裹体的等容线位置,表明变质脉体石英中的流体包裹体是在变质作用期间被捕获的部分变质流体,进一步证实了脉体是与变质作用同     

大别-苏鲁地体超高压变质岩中的副矿物——锆石

激光拉曼和锆石阴极发光图像研究结果表明,大别-苏鲁强退变质岩石(包括正片麻岩、副片麻岩、斜长角闪岩、含蓝晶石石英岩、大理岩、云母片岩等)的锆石中,均保存以柯石英为代表的超高压矿物包裹体,且记录了十分一致的超高压变质温压条件:T=732～866℃,p=2.8～4.0GPa,表明大别-苏鲁地体曾发生过巨量物质深俯冲-超高压变质的壮观的地质事件。     

Dehydration melting of ultrahigh‐pressure eclogite in the Dabie orogen: evidence from multiphase solid inclusions in garnet

Several types of multiphase solid (MS) inclusions are identified in garnet from ultrahigh‐pressure (UHP) eclogite in the Dabie orogen. The mineralogy of MS inclusions ranges from pure K‐feldspar to pure quartz, with predominance of intermediate types consisting of K‐feldspar + quartz ± silicate (plagioclase or epidote) ± barite. The typical MS inclusions are usually surrounded with radial cracks in the host garnet, similar to where garnet contains relict coesite. Barite aggregates display significant heterogeneity in major element composition, with total contents of only 57–73% and highly variable SiO₂ contents of 0.32–25.85% that are positively correlated with BaO and SO₃ contents. The occurrence of MS inclusions provides petrographic evidence for partial melting in the UHP metamorphic rock. The occurrence of barite aggregates with variably high SiO₂ contents suggests the coexistence of aqueous fluid with hydrous melt under HP eclogite facies conditions. Thus, local dehydration melting is inferred to take place inside the UHP metamorphic slice during continental collision. This is ascribed to phengite breakdown during ‘hot’ exhumation of the deeply subducted continental crust. As a consequence, the aqueous fluid is internally buffered in chemical composition and its local sink is a basic trigger to the partial melting during the continental subduction‐zone metamorphism.     

Evidence for UHP anatexis in the Shuanghe UHP paragneiss from inclusions in clinozoisite,garnet, and zircon

The Shuanghe garnet-bearing paragneiss from the Dabie ultra-high–pressure (UHP) orogen occurs as an interlayer within partially retrogressed eclogite. A first UHP metamorphic stage at 680°C, 3.8–4.1 GPa is documented by Zr-in-rutile temperatures coupled with phengite inclusions (Si = 3.55) in clinozoisite and grossular-rich garnet. Relic matrix phengite and phengite inclusions in zircon rims display lower Si of 3.42. Combined with garnet compositions and Ti-in-zircon temperatures, they provide evidence for a second UHP metamorphic stage at 800–850°C, ~3.8 GPa. Such isobaric heating at UHP conditions has not been documented so far from the adjacent eclogites and other rock types in the Dabie orogen and indicates proximity to the hot, convecting mantle wedge. The dominant mineral assemblage consisting of plagioclase, epidote, biotite, and amphibole provides evidence for widespread retrogression during the exhumation of the UHP paragneiss. Several types of polyphase mineral inclusions were identified. Phengite inclusions hosted by clinozoisite are partially replaced by kyanite and K-feldspar, whereas inclusions in host garnet consist of relic phengite, K-feldspar, and garnet, indicating limited sub-solidus dehydration of phengite by the reaction Ph→Kfs+Ky±Grt+fluid. Tightly intergrown K-feldspar and quartz are preserved as inclusions with sharp boundaries and radial cracks in garnet. Analyses of whole inclusions also show small enrichments in light rare earth elements. These inclusions are interpreted to be derived from melting of an inclusion assemblage consisting of Ph+Coe±Czo. A third type of polyphase inclusion consists of typical nanogranite (Ab+Kfs+Qz±Ep) inclusions in recrystallized metamorphic zircon. Ti-in-zircon thermometry and the Si content of phengite included in these zircon domains indicate that melting occurred at 800–850°C and 3.8–4.0 GPa during isobaric heating at UHP conditions. The partial melting event led to an equilibration of trace elements in garnet, phengite, and apatite. Using published partition coefficients between these minerals and hydrous granitic melt, the trace element composition of the UHP anatectic melt can be constrained. The melts are characterized by high LILE contents and pronounced relative enrichments of U over Th and Ta over Nb. The REE are below primitive mantle values, likely due to the presence of residual clinozoisite and garnet during partial melting. So far, no major granitic bodies have been found that share the same trace element pattern as the partial melts from the UHP anatexis of the Shuanghe paragneiss.     

大别-苏鲁区超高压变质岩的多期构造变质演化

对大别-苏鲁地区超高压(UHP)变质岩的详细构造和岩石学研究揭示了其复杂的构造变质演化历史。除前超高压事件外,至少可识别出5个相继发育的构造变质事件或阶段(D_1-D_5)。D_1和 D_2同超高压事件与三叠纪(250～230Ma)中朝克拉通和扬子克拉通间的大陆深俯冲及碰撞有关,而超高压后的 D_3和 D_4韧性变形及其伴生的减压部分熔融作用和退变质作用事件,则是超高压岩石向中上地壳折返过程中(230～140Ma)发生的。碰撞后形成的 D_4构造,主导了大别-苏鲁超高压和高压变质带区域尺度的构造格架。第5阶段的构造以摩擦或摩擦-粘性过渡性变形机制为主,并伴随有大规模的未变形的花岗质岩体就位,该期构造热事控制了现今大别-苏鲁地区的地貌学特征。新的构造和岩石学资料并结合可利用的地质年代学和地球化学等资料,提出一个涉及中朝与扬子克拉通间三叠纪大陆深俯冲、碰撞及相继超高压变质岩石向地表的多期折返构造变质演化模式。     

洋壳深俯冲超高压变质作用研究及其地质意义

洋壳深俯冲经历超高压变质作用的岩石比较稀少,是目前超高压变质作用研究的重要前沿领域,有关这方面的研究对于建立新的冷俯冲带变质作用类型、探讨地幔水流体的成因、建立更广泛的超高压变质岩石的抬升机制具有重要意义。另外,洋壳深俯冲高压变质带往往与低压高温变质带组成双变质带,对双变质带的深入研究对于完整地重塑俯冲碰撞造山带的形成演化过程具有重要意义。简要地介绍了新疆西天山洋壳深俯冲超高压变质带的研究现状和存在的问题。     

Mineral and fluid inclusions in zircon of UHP metamorphic rocks from the CCSD-main drill hole: A record of metamorphism and fluid activity

The Chinese Continental Scientific Drilling (CCSD) main drill hole (0–3000 m) in Donghai, southern Sulu orogen, consists of eclogite, paragneiss, orthogneiss, schist and garnet peridotite. Detailed investigations of Raman, cathodoluminescence, and microprobe analyses show that zircons from most eclogites, gneisses and schists have oscillatory zoned magmatic cores with low-pressure mineral inclusions of Qtz, Pl, Kf and Ap, and a metamorphic rim with relatively uniform luminescence and eclogite-facies mineral inclusions of Grt, Omp, Phn, Coe and Rt. The chemical compositions of the UHP metamorphic mineral inclusions in zircon are similar to those from the matrix of the host rocks. Similar UHP metamorphic P–T conditions of about 770 °C and 32 kbar were estimated from coexisting minerals in zircon and in the matrix. These observations suggest that all investigated lithologies experienced a joint in situ UHP metamorphism during continental deep subduction. In rare cases, magmatic cores of zircon contain coesite and omphacite inclusions and show patchy and irregular luminescence, implying that the cores have been largely altered possibly by fluid–mineral interaction during UHP metamorphism.

Abundant H₂O–CO₂, H₂O- or CO₂-dominated fluid inclusions with low to medium salinities occur isolated or clustered in the magmatic cores of some zircons, coexisting with low-P mineral inclusions. These fluid inclusions should have been trapped during magmatic crystallization and thus as primary. Only few H₂O- and/or CO₂-dominated fluid inclusions were found to occur together with UHP mineral inclusions in zircons of metamorphic origin, indicating that UHP metamorphism occurred under relatively dry conditions. The diversity in fluid inclusion populations in UHP rocks from different depths suggests a closed fluid system, without large-scale fluid migration during subduction and exhumation.     

Element mobility during continental collision: insights from polymineralic metamorphic vein within UHP eclogite in the Dabie orogen

Metamorphic dehydration and partial melting are two important processes during continental collision. They have significant bearing on element transport at the slab interface under subduction‐zone P–T conditions. Petrological and geochemical insights into the two processes are provided by a comprehensive study of leucocratic veins in ultrahigh‐pressure (UHP) metamorphic rocks. This is exemplified by this study of a polymineralic vein within phengite‐bearing UHP eclogite in the Dabie orogen. The vein is primarily composed of quartz, kyanite, epidote and phengite, with minor accessory minerals such as garnet, rutile and zircon. Primary multiphase solid inclusions occur in garnet and epidote from the both vein and host eclogite. They are composed of quartz ± K‐feldspar ± plagioclase ± K‐bearing glass and exhibit irregular to negative crystal shapes that are surrounded by weak radial cracks. This suggests their precipitation from solute‐rich metamorphic fluid/melt that involved the reaction of phengite breakdown. Zircon U–Pb dating for the vein gave two groups of concordant ages at 217 ± 2 and 210 ± 2 Ma, indicating two episodes of zircon growth in the Late Triassic. The same minerals from the two rocks give consistent δ¹⁸O and δD values, suggesting that the vein‐forming fluid was directly derived from the host UHP eclogite. The vein is much richer in phengite and epidote than the host eclogite, suggesting that the fluid is associated with remarkable concentration of such water‐soluble elements as LILE and LREE migration. Garnet and rutile in the vein exhibit much higher contents of HREE (2.2–5.7 times) and Nb–Ta (1.8–2.0 times) than those in the eclogite, indicating that these normally water‐insoluble elements became mobile and then were sunken in the vein minerals. Thus, the vein‐forming agent would be primarily composed of the UHP aqueous fluid with minor amounts of the hydrous melt, which may even become a supercritical fluid to have a capacity to transport not only LILE and LREE but also HREE and HFSE at subduction‐zone metamorphic conditions. Taken together, significant amounts of trace elements were transported by the vein‐forming fluid due to the phengite breakdown inside the UHP eclogite during exhumation of the deeply subducted continental crust.     

苏鲁仰口超高压岩石SHRIMP锆石U/Pb定年与部分熔融时限

在大型碰撞造山带中,在陆壳物质深俯冲或快速折返早期,在超高压-高压条件下,易熔组分可能发生水致或脱水部分熔融,形成花岗质熔体。在超高压-高压条件下,苏鲁超高压岩石发生过部分熔融作用,形成长英质多晶体包裹体和不同尺度的花岗质岩石, 导致可观的地球化学效应。为确定苏鲁超高压岩石部分熔融的时限,对山东仰口超高压副片麻岩和其中平行片麻理的同构造钾质花岗岩脉进行了SHRIMP锆石U/Pb地质年代学、全岩地球化学和锆石内矿物包裹体的研究。副片麻岩的锆石具有典型的核-幔-边结构。核部锆石为碎屑锆石,²⁰⁶Pb/²³⁸U年龄大于282Ma,可能反映了副片麻岩的原岩包含不同成因的物质;幔部和边部的Th/U比都小于0.1,分别给出233±3Ma和214±4Ma的²⁰⁶Pb/²³⁸U 年龄,分别对应于超高压变质和角闪岩相退变质年龄。同构造花岗岩脉是富钾过铝质花岗岩(A/CNK=1.2),锆石也具有核-幔-边结构;核部锆石年龄与副片麻岩的核部锆石年龄相当,反映了该花岗岩脉的源区可能是变沉积岩;除幔部锆石的一个点具有²⁰⁶Pb/²³⁸U年龄为234.6±3.9Ma之外,其它幔部锆石位于谐和线附近,给出²⁰⁶Pb/²³⁸U年龄为220.8±2.9Ma, 该年龄代表着该花岗岩脉的形成年龄。上述数据表明,在仰口地区,超高压岩石的部分熔融作用早于角闪岩相退变质作用。     

苏鲁超高压榴辉岩中钾长石的超高压相

在苏鲁超高压榴辉岩中,石榴石和绿辉石包含多种含钾长石的显微多晶包襄体.确定其中的钾长石是否经历过超高压变质不仅有助于限定这些长英质包裹体的成因机制,而且有助于深化理解在超高压变质过程中陆壳岩石的物理和化学行为.榴辉岩B174样品采自于中国大陆科学钻探主孔岩心.该样品的石榴石含多种单相和多相多晶包裹体,其中包括钾长石和方解石单相包裹体、钾长石+石英和钾长石+方解石多晶包裹体.激光拉曼光谱分析揭示了部分钾长石残留有超高压钾长石相--钾质钡铝沸石,表明(1)钾长石至少经历了从钾质钡铝沸石向钾长石的退变质相变;和(2)榴辉岩中含钾长石多晶包裹体形成于超高压变质条件下.