苏北榴辉岩成因类型及其形成条件

苏北榴辉岩至少存在高压壳源型（Ｈ型）、超高压壳源型（Ｕ型）和幔源型（Ｍ型）三类。其中Ｈ型榴辉岩的石榴石为铁铝榴石,具正环带结构,单斜辉石属低硬玉绿辉石,主要形成于晋宁期低温高压变质条件下的下地壳;Ｕ型榴辉岩含微粒金刚石（？）、柯石英及其假象等,发育放射状胀裂结构和正、反环带结构,石榴石为钙铝榴石,单斜辉石属高硬玉绿辉石,主要形成于印支期高温超高压变质条件下的上地幔;Ｍ型榴辉岩的石榴石属镁铝榴石,形成于晋宁期高温超高压条件下的岩石圈与软流圈交界附近。     

拉萨地块松多榴辉岩的变质演化过程:NCKMnFMASHTO体系中的相平衡关系

拉萨地块松多榴辉岩主要矿物组合为石榴子石、绿辉石、角闪石、多硅白云母、绿帘石、金红石。石榴子石环带不明显,核部成分均一,从核部到边部,镁铝榴石和钙铝榴石含量降低,可能分别记录了榴辉岩峰期及退变质过程信息。绿辉石显示微弱的成分环带,硬玉含量从核部到边部略有升高,部分绿辉石边部发育韭闪石退变质边,反映了在减压过程中外来流体进入体系的过程。多硅白云母具有高的Si含量(3.5~3.6),其中石榴石包体中的多硅白云母相对基质中的白云母有更高的Si值。本文利用Thermocalc变质相平衡模拟软件,结合详细岩相学观察,在NCKMn FMASHTO体系下,模拟松多含多硅白云母榴辉岩的变质演化过程。其中,榴辉岩峰期矿物组合为g+o+law+phn+ru,石榴石核部最大镁铝榴石值和石榴子石包体中多硅白云母最大Si值确定的榴辉岩峰期温压条件约为620℃,32×105Pa,榴辉岩经历了近等温降压的退变质过程。相平衡模拟结果表明拉萨地块松多榴辉岩经历了超高压变质作用过程,并经历了相对快速的折返过程到中部地壳层次。     

从化高围拉辉煌斑岩的初步研究

广东从化高围拉辉煌斑岩产于广州－新丰断裂带内,含花岗岩、片岩、柳辉岩等多种类型包体。拉辉煌斑岩中的石榴石属镁铝榴石－铁铝榴石系列,为榴辉岩型石榴石。其中镁铝榴石含微量Ｎａ２Ｏ,为幔源榴辉岩型石榴石;而铁铝榴石属阿尔卑斯型变质作用榴辉岩型石石,可能暗示了古老基底曾经历了高压变质作用。     

传统温压计在低温榴辉岩应用中的局限:以西南天山超高压变质带为例

榴辉岩相变质岩石的温压研究对理解高压-超高压变质带的形成和演化具有重要意义,但西南天山低温榴辉岩运用石榴石-绿辉石（-多硅白云母）温压计计算的压力普遍低于相平衡模拟的结果.为此,在Zhang et al.（2017）对含霓辉石榴辉岩研究结果的基础上,对该区域内榴辉岩及其脉体中的绿辉石进行了岩相学和矿物化学的研究,结果表明绿辉石普遍发育环带结构:从核部到边部,Fe3+含量降低,Al含量增加,Fe3+/Al比值的降低对应于霓石含量的降低和硬玉含量的升高.相平衡模拟中硬玉分子等值线的计算结果表明具有最高硬玉含量的边部绿辉石在降压阶段生长.因此,具有最高含量的硬玉组分的绿辉石并不一定代表峰期压力,在应用石榴石-单斜辉石（-多硅白云母）传统温压计时需谨慎,尤其是应用于低温的、具有复杂环带模式的矿物组合时要尤为慎重.      

榴辉岩的化学分类

以山东荣成地区的榴辉岩为例,把榴辉岩分为镁一榴辉岩、铁一榴辉岩和钙一榴辉岩三类。三类榴辉岩的岩石化学,主要造岩矿物成分都有明显差别,石榴石分别是镁铝榴石、铁铝榴石和钙铝榴石。绿辉石的硬玉分子也有不同。三类榴辉岩的化学成分限制是Mg-榴辉岩MgO>10%,石榴石以镁铝榴分子占优势,Fe-榴辉岩的MgO<10,石榴石以铁铝榴石分子占优势。Ca-榴辉岩CaO>19%,石榴石以钙铝榴石分子优势。     

苏鲁超高压榴辉岩的石榴石生长成分环带及变质作用P—T轨迹

在南苏鲁东海地区，部分超高压榴辉岩中的变斑晶石榴石具有复杂的生长成分环带和多期矿物包体组合，它们记录了超高压变质岩的多阶段变质演化过程，即绿帘角闪岩相进变质、柯石英榴辉岩相峰期变质、石英榴辉岩相和角闪岩相退变质作用。运用相关的地质温、压计，使用代表最高变质温度的变斑晶石榴石慢部（具最低的Fe／Mg比值）和与其平衡的绿辉石包体成分，获得了〉900℃和4．1～4．5GPa的超高压变质务件。联合其他变质阶段的温、压条件，一个顺时针的变质作用P—T轨迹得以建立。它的特征是进变质与退变质路径近于平行，早期退变质作用为降温、降压过程．榴辉岩石榴石生长成分环带的保存说明超高压变质岩在峰期变质阶段有非常短暂的停留时间，并以很快的折返速率抬升到地壳浅部，超高压变质岩折返过程中的明显降温是石榴石生长环带得以保存的另一个有利条件，     

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。     

胶南造山带中高,超高压变质矿

胶南造山带榴辉岩中的高压、超高压变质矿物主要有绿辉石、镁铝榴石、柯石英、金刚石、金红石等。柯石英、金刚石均呈微晶状包裹于石榴子石、绿辉石中。柯石英多已转化为石英聚晶,并使包裹它的矿和拉生放射状胀裂纹;金刚石呈近等轴八面体等,其形成压力达３．５ＧＰａ以上。榴辉岩围岩中的高压、超夺高变质矿物主要有辉石类（透辉石、霓石、暗硬玉）、钠钙质－钠质角闪石（钠闪石、镁钠闪石）、多硅白云母（３Ｔ型）、钠长石、绿帘     

榴辉岩组构运动学与大陆深俯冲——中国大陆科学钻探主孔榴辉岩的EBSD研究

中国大陆科学钻探主孔位于苏鲁超高压带南部的东海县毛北榴辉岩体之上。主孔0-600米深度的榴辉岩的塑性变形以具中等倾角的东倾面理,近南北向的水平拉伸线理、“A”型剪切褶皱和一系列平行面理的微型韧性剪切带为特征。使用电子背散射（EBSD）技术测量的主孔7个榴辉岩样品的石榴石和绿辉石的晶格优选定向（LPO）表明：石榴石基本上无序排列,而绿辉石表现出强烈的LPO。绿辉石的[001]轴近平行于拉伸线理方向,（010）面的法线和[100]轴垂直面理分布,{110}的法线形成垂直面理的环带,反映绿辉石的位错蠕变由[001]（100）和1／2〈^-110〉滑移系控制,其不对称的LPO指示了由北向南的剪切指向。根据单斜辉石的高温实验结果,毛北榴辉岩经历了800-900℃的超高压变质作用。通过构造重塑,揭示毛北榴辉岩体为剪切流变褶皱,形成于扬子板块深俯冲时的超高压变质过程。因此榴辉岩中保留的早期岩石组构特征可以为板块的深俯冲运动学和俯冲极性提供重要信息。     

柴北缘沙柳河榴辉岩岩石学及年代学初步研究

柴达木盆地北缘东端沙柳河一带榴辉岩呈布丁构造赋存在新元古代末期花岗片麻岩中 ,榴辉岩主要由石榴石、绿辉石和金红石等矿物组成 ,石榴石含有 38%～ 4 4 %的铁铝榴石、2 2 %～ 2 3%的钙铝榴石和 31%～ 38%的镁铝榴石分子 ,绿辉石含有 35 %～ 38%硬玉分子。榴辉岩变质作用过程可分为三个阶段 ,第一阶段可能为绿帘角闪岩相 ,形成了残留在石榴石中的绿帘石 +角闪石早期矿物组合 ;第二阶段为榴辉岩相 ,形成了绿辉石 +石榴石 +金红石矿物共生组合 ,其温压条件为 :T =730℃ ,P >1.6Gpa ,代表了强烈俯冲时期 ;第三阶段为高角闪岩相 ,形成了普通辉石 +角闪石 +斜长石矿物共生组合 ,其温压条件为 :T =6 70℃ ,P =0 .3～ 0 .5Gpa。变质作用演化及P -T -t轨迹反映了其地球动力学过程是板块碰撞模式。榴辉岩的颗粒锆石U -Pb年龄 (484± 3)Ma可能代表榴辉岩相变质年龄。研究表明柴北缘存在一条早古生代的高压碰撞带     

榴辉岩的弹性波速评述

文中评述了榴辉岩的密度和高温高压下的纵波速度、速度各向异性、泊松比以及榴辉岩声软化现象的成因 ,着重介绍了榴辉岩的密度和波速对探讨岩石圈物质组成、莫霍界面性质、超高压岩石对实现壳幔物质交换的重要意义。榴辉岩的密度为 3 2～ 3 6 5g·cm-3 ,其中超高压榴辉岩具有更高的密度 (3 4～ 3 6 5g·cm-3 )。榴辉岩的纵波速度 (vp)在 1GPa时为 7 3～8 9km·s-1,其裂隙闭合压力可能高于 1GPa。榴辉岩的压力系数为 0 3～ 0 4km·s-1·GPa-1,温度系数为 - 3 4× 10 -4 km·s-1·℃ -1。它具有最弱的vP 各向异性 (<3% )。超高压榴辉岩的泊松比为 0 2 54～ 0 2 75。大别山榴辉岩的密度和波速研究表明 ,现今的大别山深部地壳可能依然存在榴辉岩 ,但数量应很少 ;大别山上地幔具有同超高压榴辉岩类似的弹性特征 ;拆沉作用是解释超高压榴辉岩折返机制的重要模式之一 ;榴辉岩的形成过程包含了壳幔物质循环作用 ,一部分榴辉岩已拆沉进入深部地幔 ,另一部分则快速折返至地壳内或通过其他构造作用进一步抬升、暴露地表。     

闽北前寒武纪变质岩的P—T—t轨迹和其形成的动力学过程

闻北前寒武纪变质岩是华夏古陆基底的重要组成部分。本文通过对闽北麻源群和马面山群变质岩详细的变质变形关系的研究和石榴子石环带测定P-T-t轨迹的应用,结合构造地质和同位素年代学的资料,证实了麻源群变质岩形成于早元古代或更老年代,在早元古代末期遭受过中压、中高温变质,但在晚元古代晋宁期与中元古代形成的马面山群岩石一起经历了强烈的变质变形作用,表现为早元古代麻源群岩石遭受强烈改造,具有早期地壳再活化特点。麻源群岩石完整的晋宁期变质P-T-t轨迹不支持正常大陆碰撞的假说,它的形成与异常的地幔热流有关,很可能为一种地壳增厚和地幔减薄的动力学模式。     

中国大陆科学钻探主孔榴辉岩中石榴石和绿辉石原位激光探针分析及其成岩成矿指示意义

本文以中国大陆科学钻探主孔0～2000m岩芯中的榴辉岩为对象,运用EMPA和LA-ICP-MS技术,系统测定了榴辉岩中石榴石和绿辉石的主量与微量元素组成,并据此讨论了它们的成岩成矿意义.研究结果表明,CCSD主孔榴辉岩中石榴石富重稀土和Sc、Y、Co,而绿辉石则富中稀土和Pb、Sr、V,石榴石和绿辉石的高场强元素(特别是Nb、Ta)含量均很低.石榴石存在不同程度的Ce负异常,指示榴辉岩的形成过程中卷入有地表氧化条件下形成的风化沉积物.石榴石具有低的Zr/Y比值,绿辉石普遍具有高的Sr含量,这些特征说明榴辉岩(特别是高钛榴辉岩)的原岩可能为遭受过壳源物质混染与交代的富集地幔部分熔融的产物.高钛与低钛榴辉岩中石榴石和绿辉石在主量及微量元素组成上存在一定差别,总体而言,高钛榴辉岩中石榴石具高的MgO含量和较高的MgO/TFeO比值,以及较高的稀土和Sc含量,而绿辉石则相对富TFeO、MnO,并具有较高的Sr、Zr、Hf含量.高钛榴辉岩中石榴石和绿辉石常出现不同程度的Eu正异常,Cr含量均显著低于低钛榴辉岩.综合分析表明,高钛榴辉岩的原岩最可能为富斜长石的辉长质侵入岩,原岩组成的差异应是导致二类榴辉岩中石榴石和绿辉石矿物化学组成存在差异的主要原因.     

Garnet Types from the Cazadero Area, California

This is the third in a series of papers on glaucophane schistsfrom the Franciscan Formation near Cazadero, California. Previouspapers describe three distinct types of glaucophane-bearingFranciscan metamorphic rocks near Cazadero. The purpose of this study is to investigate the garnets presentin metamorphic types III (bedrock schists) and IV (tectonicblocks) as defined by Coleman & Lee (1963). Twenty-fourgarnet analyses are presented. Sixteen of these are from (aragonite-bearing)type III glaucophane schists, and eight are from type IV glaucophaneschists. Type IV rocks include California eclogites. Type III rocks include metabasalt, metachert, metashale, meta-ironstone,and metacarbonate that were formed under high pressure and relativelylow temperature. These rocks contain garnets that display awide range of composition, but the dominant molecules representedare consistently almandine, spessartine, and grossular. Type IV rocks are mainly metabasalts that were probably formedunder higher temperatures and pressures than type III rocks.There is a distinct difference between garnets from type IIIrocks and those from type IV (including eclogites); the lattercontainless spessartine and more pyrope, and the dominant moleculesare almandine and grossular. The four analyses of garnets fromCalifornia eclogites have an average pyrope content of aboutten molecular per cent, and they extend the range of compositionreported for eclogite garnets. Quantitative spectrographic determinations of minor elementsare listed for each of the garnets described. The values determinedfor some of the minor elements have a wide range and a capriciousdistribution over a few feet of outcrop area. As a group, both the garnets from type III rocks and those fromtype IV are pyralspites with large contents (as much as 35 molecularper cent) of ugrandite. This unusual admixture of the pyralspiteand ugrandite garnet series may have resulted in part from theconditions (high pressures and relatively low temperatures)under which the enclosing rocks were recrystallized.     

Petrogenesis of group A eclogites and websterites: evidence from the Obnazhennaya kimberlite,Yakutia

Mantle xenoliths from the Obnazhennaya kimberlite pipe, Yakutia, possess a large range of mineralogical and chemical compositions, from both group A and B eclogites. Major-element contents of the group A eclogites exhibit transitional features between the group B eclogites and peridotite. The Mg# of clinopyroxenes is 0.86–0.94, with 0.60–0.84 for garnets. Differences in concentration of LREEs exist between the Obnazhennaya group A and the well-studied group B eclogites from the Udachnaya kimberlite pipe. In general, garnets in the group A eclogites contain lower LREEs than those from the group B eclogites; however, the trend for clinopyroxene is reversed. High d ¹⁸O (5.46–7.81) values, and the positive Eu anomalies in the garnets and clinopyroxenes (Eu/Eu* 1.2–1.4) demonstrate the involvement of an oceanic crustal component in the formation of the group A eclogites. The group A eclogites formed between 21.0 and 37.6 kbar, and 711 and 923 °C, in a time interval of 1,071–1,237 Ma. An innovative model is proposed to explain the formation of the group A eclogites and websterites. It involves the reaction of a depleted mantle peridotite with TTG and carbonatite melts closely related to the subduction of oceanic crust.     

The thermal structure of continental crust in active orogens: insight from Miocene eclogite and granulite xenoliths of the Pamir Mountains

Rare ultrahigh‐temperature–(near)ultrahigh‐pressure (UHT–near‐UHP) crustal xenoliths erupted at 11 Ma in the Pamir Mountains, southeastern Tajikistan, preserve a compositional and thermal record at mantle depths of crustal material subducted beneath the largest collisional orogen on Earth. A combination of oxygen‐isotope thermometry, major‐element thermobarometry and pseudosection analysis reveals that, prior to eruption, the xenoliths partially equilibrated at conditions ranging from 815 °C at 19 kbar to 1100 °C at 27 kbar for eclogites and granulites, and 884 °C at 20 kbar to 1012 °C at 33 kbar for garnet–phlogopite websterites. To reach these conditions, the eclogites and granulites must have undergone mica‐dehydration melting. The extraction depths exceed the present‐day Pamir Moho at ～65 km depth and suggest an average thermal gradient of ～12–13 °C km^?1. The relatively cold geotherm implies the introduction of these rocks to mantle depths by subduction or gravitational foundering (transient crustal drip). The xenoliths provide a window into a part of the orogenic history in which crustal material reached UHT–(U)HP conditions, partially melted, and then decompressed, without being overprinted by the later post‐thermal relaxation history.     

一个新的花岗岩成因分类:基于变质岩深熔作用理论与大数据的证据

花岗岩目前的ISMA分类不是一个系统的分类,花岗岩分类可能需要从花岗岩的起源来考虑。花岗岩源自变质岩,可能是来自地幔或玄武质岩浆底侵带来的热导致的下地壳底部发生部分熔融的熔体形成的。因此,花岗岩与变质岩源岩有成因联系和因果关系,变质岩为母,花岗岩为子。根据埃达克岩与残留相平衡的理论,埃达克岩形成于斜长石消失线之上。那么,出现在石榴石出现线之上的是什么花岗岩呢?出现在石榴石出现线之下的又是什么花岗岩呢?本文即尝试从这个思路来探讨花岗岩的分类,并采用大数据方法予以佐证,得到的初步结果可以将花岗岩分为3类:(1)位于斜长石消失线之上的为高Sr低Y型花岗岩(高压,代表加厚的地壳);(2)位于斜长石消失线与石榴石出现线之间的为低Sr低Y类型花岗岩(中压,代表正常厚度的地壳);(3)位于石榴石出现线之下的为高Y型花岗岩(低压,代表减薄的地壳)。大数据研究的结果支持上述分类,给出的地球化学标志大体是:Sr含量为400×10^-6,Y含量为(20~35)×10^-6。     

北秦岭官坡地区高压—超高压榴辉岩岩相学及变质作用研究

北秦岭官坡地区的榴辉岩及含柯石英榴辉岩产在帮岭岩群的北侧，主要由绿辉石和石榴石组成，部分石榴石和绿辉石中含柯石英包体。此外还含有退变质的多硅白云母、角闪石、黝帘石和纳长石等矿物，根据变质矿物之间的替代关系及共生组合规律，榴辉岩退变质作用可划分为四个阶段，各阶段代表性矿物组合依次为：柯石英＋绿辉石＋石榴石；石英＋绿辉石＋石榴石；多硅白云母＋绿辉石＋石榴石＋石英；角闪石＋斜长石＋白云母＋黑云母。这四个     

High-pressure granulites: formation, recovery of peak conditions and implications for tectonics

High‐pressure granulites are characterised by the key associations garnet‐clinopyroxene‐plagioclase‐quartz (in basic rocks) and kyanite‐K‐feldspar (metapelites and felsic rocks) and are typically orthopyroxene‐free in both basic and felsic bulk compositions. In regional metamorphic areas, two essential varieties exist: a high‐ to ultrahigh‐temperature group and a group representing overprinted eclogites. The high‐ to ultrahigh‐temperature type formerly contained high‐temperature ternary feldspar (now mesoperthite) coexisting with kyanite, is associated with garnet peridotites, and formed at conditions above 900 °C and 1.5 GPa. Clinopyroxene in subordinate basic rocks is Al‐rich and textural evidence points to a high‐pressure–high‐temperature melting history. The second variety contains symplectite‐like or poikilitic clinopyroxene‐plagioclase intergrowths indicating former plagioclase‐free, i.e. eclogite facies assemblages. This type of rock formed at conditions straddling the high‐pressure amphibolite/high‐pressure granulite field at around 700–850 °C, 1.0–1.4 GPa. Importantly, in the majority of high‐pressure granulites, orthopyroxene is secondary and is a product of reactions at pressures lower than the peak recorded pressure. In contrast to low‐ and medium‐pressure granulites, which form at conditions attainable in the mid to lower levels of normal continental crust, high‐pressure granulites (of nonxenolith origin) mostly represent rocks formed as a result of short‐lived tectonic events that led to crustal thickening or subduction of the crust into the mantle. Short times at high‐temperature conditions are reflected in the preservation of prograde zoning in garnet and pyroxene. High‐pressure granulites of both regional types, although rare, are known from both old and young metamorphic terranes (e.g. c. 45 Ma, Namche Barwa, E Himalaya; 400–340 Ma, European Variscides; 1.8 Ga Hengshan, China; 1.9 Ga, Snowbird, Saskatchewan and 2.5 Ga Jianping, China). This spread of ages supports proposals suggesting that thermal and tectonic processes in the lithosphere have not changed significantly since at least the end of the Archean.