CCSD主孔超高压榴辉岩金红石中的矿物包裹体研究

金红石是榴辉岩中的主要含钛副矿物。中国大陆科学钻探工程（CCSD）主孔100～2000m岩心样品中，金红石榴辉岩、多硅白云母榴辉岩和蓝晶石榴辉岩中都程度不等地含有金红石。金红石既可以与其他矿物一起被石榴石、绿辉石等主要变质矿物包裹，也可以包裹其他矿物。本文利用电子探针技术，对CCSD所揭示的超高压榴辉岩的金红石中的矿物包裹体进行了鉴定和分析。结果显示，绿辉石、富铪锆石、高铝榍石、韭闪石和红闪石、斜黝帘石等矿物包裹体形成于榴辉岩相进变质至峰期变质阶段；随着超高压变质带快速折返，榴辉岩经受强烈的退变质作用，包括金红石、绿辉石在内的多种矿物都经受了退变质作用，与金红石共生的钛铁矿完全或者部分退变成含铁金红石和钛铁晶石。在退变的金红石中，还发现了透辉石＋斜长石后成合晶、低铝榍石、镁绿闪石等退变质矿物组合。     

北秦岭松树沟及其邻区高压-超高压榴辉岩的确定及其构造地质意义

详细的岩相学观察和激光拉曼矿物包裹体研究,在松树沟及其邻区秦岭群片麻岩中的榴闪岩和斜长角闪岩透镜体中发现了石榴石+绿辉石的典型榴辉岩相矿物组合,以及指示超高压变质的微粒柯石英包裹体,表明北秦岭松树沟及其邻区是超高压变质作用的产物。北秦岭松树沟超镁铁质岩体旁侧的榴闪岩一直以来都存在着接触交代变质(黄月华等,1984)、麻粒岩相变质(钱加慧等,2013)和退变榴辉岩(刘良等,2013;Zhang et al.,1999)等多种成因观点。本次研究在该榴闪岩的基质矿物角闪石的核部、石榴石变斑晶的幔部包裹体及锆石包体中都发现了残留绿辉石,而且发现石榴石变斑晶保存了很好的进变质矿物包裹体和主、微量元素成分环带,表明松树沟榴闪岩为榴辉岩相退变质的产物,至少经历了从角闪岩相到榴辉岩相再到角闪岩相的三阶段顺时针p-T演化。另外,采用激光拉曼光谱分析方法,对丹凤地区秦岭群片麻岩的多个榴闪岩和斜长角闪岩透镜体进行了详细的锆石包裹体矿物学分析,在其中的一个斜长角闪岩的锆石中发现了超高压矿物柯石英,表明该斜长角闪岩为超高压榴辉岩退变质的产物。LA-ICP-MS锆石U-Pb年代学研究,得到松树沟榴辉岩的峰期变质年龄为(500±8)Ma,原岩结晶时代为(796±16)Ma;得到丹凤地区斜长角闪岩的峰期变质时代为(498±3)Ma,同时得到~450 Ma和~420 Ma两期退变质事件年龄;得到斜长角闪岩的围岩片麻岩的变质年龄为(502±4)Ma。其中榴辉岩和斜长角闪岩的~500 Ma的变质年龄分别来自锆石的石榴石+绿辉石以及柯石英包体的微区,应代表本区高压-超高压榴辉岩相变质的年龄。该年龄与秦岭岩群中已发现的官坡含金刚石榴辉岩(~500 Ma,杨经绥等,2002;陈丹玲等,2011)、清油河含金刚石斜长角闪岩(490±5.8 Ma;Wang et al.,2014)的峰期变质年龄一致,也与秦岭岩群区域片麻岩的~500 Ma的变质时代在误差范围内完全一致(刘良等,2013;Diwu et al.,2014),表明松树沟及其邻区榴辉岩与北秦岭造山带已发现的高压-超高压变质岩石一起都应是古生代大陆深俯冲作用的结果。     

西藏松多榴辉岩矿物出溶体研究

西藏松多榴辉岩中的石榴石和单斜辉石中发育有大量的矿物出溶体。电子探针能谱分析结果表明,石榴石中的出溶体为金红石,绿辉石中的出溶体为石英和富钾质矿物(钾长石)。根据石榴石-绿辉石-多硅白云母矿物温压计计算出的松多榴辉岩变质温压范围接近石英-柯石英相转变线,结合这些出溶体的存在,指示了西藏松多榴辉岩曾经历过超高压变质作用,这为松多榴辉岩的形成条件提供了重要证据。     

大别地区榴辉岩中几种超高压变质矿物研究

根据镜下观察,在大别地区东南部榴辉岩中陆续发现柯石英、金刚石和文石等三种超高压变质矿物,拉曼分子探针检测进一步证实了这些发现。柯石英和文石均被包裹于石榴石或绿辉石晶体之内,而基质中则分别以低压多型变体石英和方解石的形式存在,说明其保存除快速构造抬升的外部条件外,还与寄主矿物机械阻力及晶内低压缩性有关。作为榴辉岩相的早期共生矿物,它们的出现证明该区榴辉岩经历了超高压变质作用。     

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。     

高压超高压变质作用中的流体

文章强调了高压和超高压变质岩中流体包裹体的研究意义，重点论述了几个问题：（１）高压和超高压变质岩中流体包裹体的成分以含Ｎ２量高为特点，在大别山含柯石英榴辉岩中找到的高压榴辉岩阶段捕获的原生包裹体，其中气相组分含ＣＯ（摩尔分数）为１４％，表明流体来源于深部。原生流体包裹体的保存，要求在ｐ－Ｔ区间内的抬升轨迹与等容线近于平行。（２）在大别山高压和超高压榴辉岩中首次确认熔融包裹体的存在，由硅酸盐玻相和以ＣＯ２为主要成分的气相组成，并发现熔融包裹体中的玻相成分与主矿物相近。（３）高压和超高压变质期间的局部流体迁移可由榴辉岩中流体包裹体和矿物同位素成分（Ｈ－Ｃ－Ｏ）来显示。（４）高压和超高压变质中流体－熔体－岩石（矿物）相互作用是一个非常复杂的过程，并证实在榴辉岩相ｐ－Ｔ条件下岩石的部分熔融。（５）变质流体的成分与变质级之间存在着相关关系。     

苏鲁超高压变质带桃行榴辉岩及高压脉体中流体包裹体研究

桃行榴辉岩是苏鲁超高压变质带中段主要榴辉岩体密集分布区之一。流体包裹体研究表明,榴辉岩矿物及高压脉体石英中捕获有五种类型的流体包裹体：在超高压-高压榴辉岩相条件下捕获的N2±CH4包裹体;在榴辉岩发生麻粒岩相叠加变质作用期间被捕获的B型纯CO2液相包裹体;在高压榴辉岩重结晶阶段被捕获的C型CO2-H2O包裹体和D型高盐度水溶液包裹体;超高压岩石折返过程中的最晚阶段（角闪岩相退变质甚至更晚）捕获的E型低盐度水溶液包裹体。利用榴辉岩矿物及高压脉体石英中捕获的流体包裹体类型及期次可以重建超高压变质作用板片折返过程中的流体性状与演化,而石榴石中捕获的纯CO2包裹体为本区榴辉岩相岩石遭受了麻粒岩相叠加提供了佐证。     

大别山超高压榴辉岩带榴辉岩的特征和变质作用

大别山超高压柯石英榴辉岩带中多处产出含柯石英榴辉岩,岩石中广泛分布柯石英假象。它们产在片麻岩和大理岩中,并有不同的特征矿物组合。与鄂北等地高压型榴辉岩比较,超高压(柯石英)榴辉岩的绿辉石富硬玉组分,而石榴石为一般的富铁铝榴石贫镁铝榴石的石榴石。钙质角闪石和钠钙质冻蓝闪石是超高压(柯石英)榴辉岩中主要的次生角闪石类型。榴辉岩的原岩是陆内拉张过程中形成的广义拉斑玄武岩,它们在中朝一扬子大陆板块汇聚造山的俯冲大地构造背景中,发生渐进变质。变质时地热增温率极低。造山运动后期,榴辉岩随构造运动抬升又经历两阶段迭加变质。     

大别超高压变质过程中部分熔融作用的地球化学约束

报道了大别超高压变质带西部麻城四道河榴辉岩-围岩剖面系统的元素和同位素地球化学研究成果, 对超高压变质榴辉岩在俯冲和折返过程中的部分熔融作用进行了探讨. 研究表明, 榴辉岩原岩性质类似于N-MORB, 其长英质围岩可分为TTG片麻岩和含石榴石花岗岩; 两类长英质围岩Sm -Nd同位素特征与其寄主的榴辉岩相似; REE特征、w (Nb)/w (Ta) 比值、Nd同位素组成及锆石U -Pb定年等地球化学证据支持了TTG片麻岩为大别地区陆壳俯冲过程中发生部分熔融作用而形成, 其与超高压榴辉岩的关系属特殊的异地关系; 含榴花岗岩为超高压榴辉岩折返过程中的部分熔融作用形成, 但因其形成环境为石榴石稳定场的深度, 故含榴花岗岩与超高压榴辉岩被视为近似原地的构造关系.      

鲁东南岚山头超高压变质岩流体包裹体特征与板片折返史

鲁东南岚山头含柯石英榴辉岩主要产于花岗质片麻岩内,是苏鲁超高压变质带主要榴辉岩体密集分布区之一。流体包裹体研究表明,榴辉岩矿物及细脉石英中捕获有四种类型包裹体:在超高压-高压榴辉岩相条件下捕获的 N_2±CO_2包裹体;在高压榴辉宕重结晶阶段被捕获的 CO_2-H_2O 包裹体和含子矿物高盐度 H_2O 溶液包裹体:在超高压岩石折返过程中的最晚(角闪岩相退变质甚至更晚)阶段捕获的低盐度 H_2O 溶液包裹体。利用榴辉岩矿物及脉体石英中捕获的流体包裹体相互期次关系,可以对本区超高压变质作用板片折返过程中的流体演化史进行重建。     

Fluids in deeply subducted continental crust: Petrology, mineral chemistry and fluid inclusion of UHP metamorphic veins from the Sulu orogen, eastern China

The complex vein associations hosted in southern Sulu ultrahigh-pressure (UHP) eclogites contain quartz ± omphacite (or jadeite) ± kyanite ± allanite ± zoisite ± rutile ± garnet. These minerals have chemical compositions similar to those of host eclogites. Inclusions of polycrystalline quartz pseudomorphs after coesite were identified in vein allanite and garnet, and coesite inclusions were found in vein zircon. These facts suggest that the veins together with host eclogites have been subjected to synchronous UHP metamorphism. The vein minerals contain relatively high concentrations of rare earth elements (REE), high-field-strength elements (HFSE) and transition metal elements (TME). A kyanite-quartz vein has a whole-rock composition similar to adjacent UHP metamorphic granitic gneisses. Abundant primary multi-solid fluid inclusions trapped within UHP vein minerals contain complex daughter minerals of muscovite, calcite, anhydrite, magnetite, pyrite, apatite, celestite and liquid and gas phase of H₂O with solids up to 30-70% of the inclusion volume. The presence of daughter minerals anhydrite and magnetite indicates the subduction fluids were oxidizing, and provides a possible interpretation for the high oxygen fugacity of subduction zone magmas. These characteristics imply that the UHP vein minerals were crystallized from supercritical silicate-rich aqueous fluids that were in equilibrium with peak-UHP minerals, and that the fluids in deeply subducted continental crust may contain very high concentrations of silicate as well as HREE, HFSE and TME. Such fluids might have resulted in major fractionation between Nb and Ta, i.e. the UHP fluids have subchondritic Nb/Ta values, whereas the host eclogites after extraction of the fluids have suprachondritic Nb/Ta values. Therefore, voluminous residual eclogites with high Nb/Ta ratios may be the complementary suprachondritic reservoir capable of balancing the subchondritic depleted mantle and continental crust reservoirs.     

北苏鲁威海地区超基性岩的原岩形成时代和超高压变质时代

超基性岩是苏鲁超高压变质地体中一类特殊且十分重要的岩石类型,它们通常呈规模不一的块状、条带状或不规则透镜状 (体) 赋存于区域大面积出露的花岗质片麻岩中。锆石中矿物包体激光拉曼测试、阴极发光图像分析和不同性质锆石LA-ICP-MS U-Pb定年等综合研究结果表明,北苏鲁威海地区含橄榄石辉石岩 (样品W1和W2) 中锆石的成因十分复杂,可进一步划分3种不同类型锆石。其中第一类锆石呈自形-半自形晶,阴极发光图像显示清晰的岩浆结晶环带,矿物包体主要为Ol+Cpx+Ap, 记录的²⁰⁷Pb/²⁰⁶Pb年龄为1835~1845Ma,应代表含橄榄石辉石岩的原岩形成时代;第二类为变质重结晶锆石,呈半自形-他形晶,阴极发光图像显示模糊的岩浆结晶环带,矿物包体与第一类完全一致,记录的²⁰⁶Pb/²³⁸U年龄变化范围大,为250~784Ma之间,表明部分继承性岩浆结晶锆石明显受到后期岩浆-变质热事件的影响而发生不完全重结晶和Pb丢失,进而使其记录的年龄相对偏新;第三类锆石呈他形晶,为典型的变质锆石,阴极发光图像十分均匀,矿物包体相对少见,主要为Grt+Cpx,记录的²⁰⁶Pb/²³⁸U年龄为230~234Ma, 且与苏鲁地体榴辉岩及其围岩中含柯石英锆石微区记录的超高压变质年龄 (225~235Ma) 十分一致,应代表含橄榄石辉石岩的峰期超高压变质时代。超基性岩中超高压变质锆石的准确识别表明苏鲁地体在峰期超高压变质阶段的确存在流体,流体的存在对超高压变质锆石的形成起着至关重要的作用。该项研究不仅准确厘定北苏鲁威海地区超基性岩的原岩形成时代和超高压变质时代,而且对于深入探讨苏鲁-大别超高压地体流体行为、演化规律及其水-岩相互作用机理具有重要的科学意义。     

Multiple partial melting events in the Sulu UHP terrane: zircon U–Pb dating of granitic leucosomes within amphibolite and gneiss

Thin layers and lenses of granitic leucosome are widely distributed within amphibolites, paragneisses and orthogneisses of the Sulu UHP terrane. They are parallel to, or cross‐cut, foliations in the host rocks at different scales and show evidence of coalescence and migration to form centimetre‐ to decimetre‐scale segregations. Variously migmatized rocks extend at least 350 km from SW Sulu (Maobei) to NE Sulu (Weihai), in a band at least 50 km wide. A combined study of mineral inclusions, cathoduluminescence (CL) images, U–Pb LA‐ICP‐MS dates, and in‐situ trace element compositions of zircon provide clear evidence on the nature and timing of partial melting in these UHP rocks. Most zircon from the granitic leucosomes occurs as distinct overgrowths around inherited (igneous or metamorphic) cores or as new, euhedral crystals. The overgrowths and new crystals commonly show perfectly euhedral shapes, have pronounced oscillatory zoning and contain felsic mineral inclusions, such as Kfs + Pl + Qtz ± Ilm ± monazite (Mon). In contrast, the inherited igneous or metamorphic cores are rounded or irregular, contain low‐P or UHP mineral inclusions and show clear dissolution textures. These data suggest that the new zircon is anatectic in origin and that it grew during partial melting of the UHP rocks. The REE patterns of the anatectic zircon show steep slopes from the HREE to LREE with strongly to moderately negative Eu anomalies (Eu/Eu* = 0.31–0.72) and pronounced positive Ce anomalies (Ce/Ce* = 6.8–26.5). Abundant U–Pb spot analyses of the anatectic zircon reveal two discrete and meaningful ages of partial melting within the Sulu UHP terrane. Anatectic zircon from 12 granitic leucosomes within amphibolites, paragneisses, and orthogneisses from Sulu UHP slices II and III yields consistent mean U–Pb ages of 219.0 ± 1.2 to 218.3 ± 1.6 Ma, 218.8 ± 2.0 to 217.3 ± 1.7 Ma and 218.2 ± 1.4 to 215.0 ± 1.5 Ma, respectively. In contrast, anatectic zircon from six granitic leucosomes within paragneisses and orthogneisses from Sulu UHP slice III records younger mean U–Pb ages of 151.9 ± 1.3 to 151.1 ± 1.8 Ma and 155.9 ± 1.8 to 153.7 ± 1.7 Ma, respectively. These data imply that the Sulu UHP terrane experienced two Mesozoic partial melting events. The first partial melting event (219–215 Ma) was probably associated with a Late Triassic granulite facies stage of ‘hot’ exhumation, whereas the second (156–151 Ma) is interpreted as the result of Middle‐Late Jurassic extension and thinning of the previously thickened crust of the Sulu UHP terrane. Both partial melting events induced extensive retrograde metamorphism of the eclogites and their country rocks.     

苏鲁三清阁榴辉岩中柯石英的发现及其地质意义探讨

在苏鲁三清阁多硅白云母榴辉岩中发现了柯石英包体,该榴辉岩与超高压含菱镁矿大理岩共生。石榴石中存在的柯石英残晶和多晶石英假相包体表明榴辉岩的变质压力超过2.8 GPa。运用石榴石–单斜辉石Fe2+–Mg温度计和多硅白云母压力计估算结果表明,矿物核部的平衡压力为3.1～3.5 GPa（T ＝650～689℃）,边部的平衡压力为2.9~3.3 GPa（T＝652～671℃）。与石榴石伴生的绿辉石普遍发育石英出溶结构。在磷灰石中观察到金属硫化物出溶体。磷灰石富含OH,F,Cl和S等挥发份,这些挥发性组分的深循环对地壳和地幔之间的相互作用研究具有重要意义。通过磷灰石,苏鲁—大别俯冲带能够将大量（～80 000 Mt）OH,F和Cl携带到地幔深处。     

Petrology of the Non-mafic UHP Metamorphic Rocks from a Drillhole in the Southern Sulu Orogenic Belt, Eastern-Central China

The Drillhole ZK703 with a depth of 558 m is located in the Donghai area of the southern Sulu ultrahigh-pressure (UHP) metamorphic belt, eastern China, and penetrates typical UHP eclogites and various non-mafic rocks, including peridotite, gneiss, schist and quartzite. Their protoliths include ultramafic, mafic, intermediate, intermediate-acidic, acidic igneous rocks and sediments. These rocks are intimately interlayered, which are meters to millimeters thick with sharp and nontectonic contacts, suggesting in-situ metamorphism under UHP eclogite facies conditions. The following petrologic features indicate that the non-mafic rocks have experienced early-stage UHP metamorphism together with the eclogites: (1) phengite relics in gneisses and schists contain a high content of Si, up to 3.52 p.f.u. (per formula unit), while amphibolite-facies phengites have considerably low Si content (<3.26 p.f.u.); (2) jadeite relics are found in quartzite and jadeitite; (3) various types of symplectitic coronas and pseud     

Tracing the protolith, UHP metamorphism, and exhumation ages of orthogneiss from the SW Sulu terrane (eastern China): SHRIMP U–Pb dating of mineral inclusion-bearing zircons

Orthogneisses are the major country rocks hosting eclogites in the Sulu UHP terrane, eastern China. All of the analyzed orthogneiss cores from the main drilling hole of the Chinese Continental Scientific Drilling Project (CCSD-MH) have similar major and trace element compositions and a granite protolith. These rocks have relatively high LREE/HREE ratios, strong negative Eu anomalies (Eu/Eu*=0.20–0.39), and negative Ba anomalies (Ba/Ba*=0.25–0.64). Coesite and coesite-bearing UHP mineral assemblages are common inclusions in zircons separated from orthogneiss, paragneiss, amphibolite, and (retrograded) eclogite of the CCSD-MH. This suggests that the eclogite, together with its country rocks, experienced in situ ultrahigh-pressure (UHP) metamorphism. Laser Raman spectroscopy and cathodoluminescence (CL) images show that zircons from the orthogneisses are zoned and that they have distinct mineral inclusions in the different zones. Most zircons retain early magmatic cores with abundant low-pressure mineral inclusions, which are mantled with metamorphic zircon-containing inclusions of coesite and other UHP minerals. The outermost rims on these grains contain low-pressure mineral inclusions, such as quartz and albite. SHRIMP U–Pb dating of the zoned zircons gives three discrete and meaningful groups of ages: Proterozoic ages for the protolith, 227±2 Ma for the coesite-bearing mantles, and 209±3 Ma for the amphibolite facies retrograde rims. The widespread occurrence of UHP mineral inclusions in zircons from the Sulu metamorphic belt dated at about 227 Ma suggests that voluminous continental crust experienced late Triassic subduction to depths of at least 120 km and perhaps more than 200 km. Eighteen million years later, the terrane was rapidly exhumed to midcrustal levels, and the UHP rocks were overprinted by amphibolite facies metamorphism. The exhumation rate deduced from the zircon age data and previously obtained metamorphic P–T data is estimated to be 5.6–11.0 km/Ma. Such rapid exhumation of the Sulu UHP terrane may be due to the buoyancy forces produced by subduction of low-density continental material into the deep mantle.     

Partial melting of metapelites at ultrahigh-pressure conditions, Greenland Caledonides

Eclogite, orthogneiss and, by association, metapelite from an island at 78°N in North‐East Greenland experienced ultrahigh‐pressure (UHP) metamorphism at approximately 970 °C and 3.6 GPa, at the end of the Caledonian collision, 360–350 Ma. Hydrous metapelites contain abundant leucocratic layers and lenses composed of medium‐grained, anhedral, equigranular quartz, antiperthitic plagioclase and K‐feldspar with minor small garnet and kyanite crystals. Leucosomes are generally parallel to the matrix foliation, are interlayered with residual quartz bands, anastomose around residual garnet and commonly cross‐cut micaceous segregations. Textures suggest that the leucosomes crystallized from a syntectonic melt, but crystallized at the end of local high‐grade deformation. The metapelite outcrop is < 1.5 km from kyanite eclogites with confirmed coesite, but the metapelites lack coesite and palisade textures diagnostic of coesite pseudomorphs. They do contain highly fractured garnet megacrysts with polycrystalline quartz inclusions (some surrounded by radial fractures) and Ti‐rich phengite inclusions that suggest the former presence of coesite. Polyphase inclusions in garnet contain reactants and products of the inferred dehydration melting reaction: Phe + Qtz = Ky + Kfs + Rt + melt. The reactants are thought to have been early inclusions of hydrous phases within garnet that melted and then crystallized new phases. Garnet surrounding these inclusions has patchy zoning with elevated Ca, consistent with experiments that produced similar patchy microstructures in garnet around inclusions with an unequivocal melt origin. The peak UHP metamorphic assemblage in these rocks is inferred to have been phengite, coesite, garnet, kyanite, rutile, fluid ± omphacite ± epidote. Phase diagrams indicate that dehydration melting of phengite in this assemblage would have occurred after decompression from peak pressure, but still above the coesite to quartz transition. Unusual crown‐ and moat‐like textures in garnet around some polycrystalline quartz inclusions are also consistent with the inference that melting took place at UHP conditions.     

隐藏在苏鲁地体斜长角闪岩锆石中超高压变质作用的信息

运用激光拉曼和阴极发光技术，配备电子探针测试，发现苏鲁地体地表露头和中国大陆科学钻探工程预先导孔CCSD-PP1和CCSD-PP2斜长角闪岩锆石中均保存以柯石英为代表的典型超高压矿物组合：柯石英 石榴石 绿辉石 金红石；柯石英 石榴石 绿辉石；柯石英 石榴石 绿辉石 多硅白云母 金红石 磷灰石；柯石英 绿辉石 金红石；柯石英 菱镁矿。该类矿物包体组合与苏鲁地体超高压榴辉岩的峰期矿物组合十分相似，表明斜长角闪岩可能是由超高压变质的榴辉岩在构造抬升过程中退变质而成。     

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.     

Source of coesite inclusions within inherited magmatic zircon from Sulu UHP rocks, eastern China, and their bearing for fluid–rock interaction and SHRIMP dating

The 5-km deep Chinese Continental Scientific Drilling Main Hole penetrated a sequence of ultrahigh pressure (UHP)-metamorphic rocks consisting mainly of eclogite, gneiss and garnet-peridotite with minor schist and quartzite. Zircon separates taken from thin layers of schist and gneiss within eclogite were investigated. Cathodoluminescence images of zircon grains show that they have oscillatory zoned magmatic cores and unzoned to patchy zoned metamorphic rims. Zircon rims contain rare coesite and calcite inclusions whereas cores contain inclusions of both low- P minerals (e.g. feldspar, biotite and quartz) and coesite and other eclogite-facies minerals such as phengite and jadeite. The zircon cores give highly variable ²⁰⁶Pb/²³⁸U ages ranging from 760 to 431 Ma for schist and from 698 to 285 Ma for gneiss, and relatively high but variable Th/U ratios (0.16–1.91). We suggest that the coesite and other eclogite facies mineral inclusions in zircon cores were not magmatic but formed through metasomatic processes caused by fluids during UHP metamorphism, and that the fluids contain components of SiO₂, Al₂O₃, K₂O, FeO, MgO, Na₂O and H₂O. Metasomatism of the Sulu UHP rocks during continental subduction to mantle depths has partly altered magmatic zircon cores and reset isotopic systems. This study provides key evidence that mineral inclusions within magmatic zircon domains are not unequivocal indicators of the formation conditions of the respective domain. This finding leads us to conclude that the routine procedure for dating of metamorphic events solely based on the occurrence of mineral inclusions in zoned zircon could be misleading and the data should be treated with caution.