地壳不同构造层次岩石变形机制及其构造岩类型

构造岩记录地壳构造变形演化重要信息,其成因、分类与命名一直没有统一认识。本文对构造岩变形机制、控制因素和构造岩分类进行系统总结。认为构造岩形成受物质成分、变形机制、应变速率、流体、温度、压力等因素控制,是物质成分与物理化学条件、变形机制等众多变量的函数。变形机制包括破裂作用、碎裂流动、晶质塑性、物质扩散、重结晶作用和超塑性流动,不同变形机制出现在不同地壳构造层次中,形成不同的显微组构。依据成因机制、物质组成和组构等标志对构造岩分类与命名进行重新修订,将构造岩划分为碎裂岩系列和变质构造岩系列,前者发育在地壳浅构造层次上,以破裂作用和碎裂流动变形机制为主;后者发育在中深部构造层次上,以晶质塑性、重结晶作用、物质扩散作用和超塑性流动作用为主。碎裂岩系列划分碎裂岩、角砾岩、微角砾岩、超碎裂岩、断层泥和假玄武玻璃;变质构造岩系列划分为构造片岩、糜棱岩和构造片麻岩。依据岩石流变性质、变形机制和构造岩分布,地壳构造层次划分为:脆性域,变形机制以碎裂作用和碎裂流动为主,发育碎裂岩系列;脆-韧性转换域,以晶质塑性、物质扩散和重结晶作用为主,并伴随有碎裂作用,形成糜棱岩、千糜岩和构造片岩;低温韧性域,以晶质塑性、物质扩散和重结晶作为主,发育糜棱岩与构造片岩;高温韧性域,以超塑性蠕变和重结晶作用为主,形成构造片麻岩。     

内蒙古大青山北公益明—高家村逆冲型韧性变形带特征及其地质意义

公益明—高家村韧性变形带发育太古代花岗绿岩带与高级区接触带附近,在空间上呈近东西方向展布,是由北向南逆冲型韧性变形带。该韧性变形带遭受两期韧性变形作用改造,早期发生在地壳深部构造层次上角闪岩相条件下,以韧性变形机制为主。晚期变形作用发生地壳中浅部构造层次上,以韧脆性变形作用为主。韧性变形带内主要构造岩为构造片岩,是以新生的片状、纤状矿物为主的构造岩。宏观与微观不对称流动组构表明,韧性变形带运动方向为由北向南逆冲。韧性挤压逆冲变形作用发生太古代晚期,是由北部花岗绿岩带与南部高级区相互拼贴碰撞有关。     

辽西医巫闾山变质核杂岩中间流变层变形特征

医巫闾山变质核杂岩具有典型的三层结构:变质核、中间韧性流变层和上盘脆性变形的盖层。由中新元古界沉积岩系组成的韧性流变层是医巫闾山变质核杂岩的重要组成部分,它们主要分布在变质核杂岩东部、北部和南部一带,遭受了低绿片岩相的变形变质作用改造,其内发育了各种顺层流变组构。中间韧性流变层同构造石英脉的流体包裹体分析结果表明:均一温度为150~170℃,密度为0.96~0.98g/cm3,压力为40~50 MPa,形成深度为5~6 km。依据流体包裹体分析数据,结合显微构造特征分析,韧性流变层变形作用发生在地壳浅部层次低温低压环境中,以韧脆性变形机制为主。     

构造片麻岩含义及其成因机制

构造片麻岩是地壳深部构造层次上韧性变形带主要的构造岩类型之一,其内保留了大量岩石流变特征的重要信息,在前寒武纪高级变质岩区广泛发育。构造片麻岩是由强烈塑性变形作用、变质作用和部分熔融作用共同作用形成的动力变质构造岩,是一种宏观上具有明显的强塑性流变特征而没有明显粒径减小的构造岩;在露头和手标本上以密集条带状构造和片麻状构造为特征,在微观上为典型三边平衡结构和复晶石英条带构造。熔体存在是控制影响构造片麻岩形成的主要因素之一,主要变形机制为扩散蠕变和颗粒流动,使岩石整体产生巨大应变,而单个矿物晶体不产生变形。构造片麻岩带可以分为3种不同类型：同变质期的层状构造片麻岩带、退变质期的线性构造片麻岩带和网状构造片麻岩带。     

部分熔融与高级变质岩流变机制——以内蒙古大青山高级变质岩为例

部分熔融作用与高级变质岩变形作用是相互制约,变形作用能够提高岩石部分熔融程度,降低熔融温度。熔体存在影响和制约岩石强度和变形机制。大青山高级岩经历了下部地壳构造层次变质变形和深熔作用改造,形成了复杂构造要素组合。宏观与微观构造特点表明:高级变质岩变形机制主要为熔体增强颗粒边界扩散和颗粒流动,使岩石发生大规模的塑性流动。在宏观上形成了不对称流动组构、熔融线理、岩石和矿物条带、层内底辟褶皱和大型穹窿构造。但是,在微观上矿物颗粒变形不明显,晶内变形组构不发育,表现为三边平衡结构,与静态结晶变质岩结构相似,形成了地壳深部构造层次上变质构造岩-构造片麻岩。     

南天山榆树沟麻粒岩相构造岩研究

榆树沟麻粒岩相构造岩宏观上呈糜棱岩带和糜棱岩化带产出,发育强烈流变叶理;微观上主要造岩矿物发育各种塑性变形显微构造。变形过程中同种造岩矿物的动态重结晶新晶与塑变残斑（残晶） 之间化学成分变化不明显, 表明在变形期间水活度低,以位错蠕变为主。该构造岩形成于深地壳麻粒岩相变质的晚期阶段,是地体在早期阶段于下地壳底部－上地幔顶部发生高压麻粒岩相变质作用后因构造抬升进入深地壳麻粒岩相环境下发生退变质和强烈韧性剪切变形的产物, 其形成后经历了快速的构造折返过程。     

内蒙古大青山高级变质岩韧性剪切带及其流变机制

大青山高级变质岩不仅记录华北克拉通早期大陆形成演化历史,也保留了中下部地壳岩石流变信息,它们经历了下部地壳构造层次高角闪岩相-麻粒岩相条件变质变形、深熔作用改造,形成了复杂构造样式和构造要素组合.韧性剪切带是高级变质岩中主要构造形迹,控制着早前寒武纪高级变质岩主体构造格架.依据野外地质产状、变形特征与构造要素叠加改造关系,韧性剪切带划分为早期近水平顺层伸展型和晚期陡倾韧性剪切带.近水平顺层伸展韧性剪切带呈残留状保留在后期变形改造较弱部位上,主要沿着不同地质单元或者岩性层界面上发育,是在伸展变形体制下形成的.晚期陡倾韧性剪切带呈近东西方向展布,规模较大,叠加和改造早期构造形迹,形成于晚期造山挤压构造环境中,以左行滑移为主.这两种韧性剪切带都形成于地壳中深部构造层次高角闪岩相-麻粒岩相条件下,变形机制主要为熔体增强颗粒边界扩散和颗粒流动,使岩石发生大规模的塑性流动.在宏观上形成了不对称流动组构、条纹条带构造、熔融线理、层内流动褶皱等构造形迹,在微观上矿物晶体没有发生明显塑性变形,均匀消光,晶体为三边平衡结构,与静态变质结构相似,形成了地壳深部构造层次上变质构造岩-构造片麻岩.      

江西大背坞地区浅变质碎屑岩中韧性剪切带变形特征

浅变质碎屑岩中韧性剪切带的变形特征不同于长英质岩石中的韧性剪切带。以江西大背坞地区为例,阐述了在浅变质碎屑岩中鉴别韧性剪切带的标志,提出这种变形的构造岩的分类方案,同时对大背坞地区韧性剪切带进行应变测量和剪切位移估算,最后在岩石组构特征和综合分析基础上指出这种韧性变形机制是粒间滑动和粒内变形,其形成深度５～８ｋｍ、温度２５０～３５０℃、压力０１０～０２０ＧＰａ,是一种发育在地壳浅层次的低温低压条件下的韧性变形,其变形变质作用相当于低绿片岩相。     

内蒙古大青山深层次韧性剪切带的特征及其成因机制

内蒙古大青山高级变质杂岩区发育多条近东西向、平行相阃排列的深层次韧性剪切带.其主要位于不同岩性的边界,以发育各种条带构造及S-C组构为特征.韧性剪切带与其间弱变形域的应变强弱相间,连续变化的特点可用变形分解理论合理解释.剪切带中的构造岩具有明显不同于中浅层次糜棱岩的微观组构特征,主要表现为无残斑基质之分,广泛发育复晶石英条带,长石多呈三边平衡结构等,反映了地壳深层次的变形主要受扩散蠕变及熔体强化的颗粒流动机制控制.同构造矿物组合与石榴石-黑云母矿物时温压计(710℃,0.6 GPa)显示变形环境为高角闪岩相-麻粒岩相.同构造岩体单颗粒锆石U-Pb同住素年龄在1900 Ma～2200 Ma之间,推测剪切带大致形成于早元古代.韧性剪切带的构造形迹暗示其形成于斜向挤压(NNE-SSW)的构造环境,结合年代学资料及当时的大地构造环境,可认为其是阴山陆块与鄂尔多斯陆块斜向(NNE-SSW)水平会聚导致应变分解的产物.     

辽西兴城—台里韧性剪切带北段变形特征

辽西兴城—台里地区发育系列花岗质岩石,强烈构造变形特征均显示其具有韧性剪切带的特点。对剪切带北段进行详细宏微观构造解析,结合岩石变形强度差异性分析、有限应变测量、石英C轴EBSD测试以及古差异应力值估算等研究,结果表明剪切带内花岗质片麻岩和眼球状花岗质片麻岩具有NEE向左行剪切变形特征,变形岩石为S-L构造岩,应变类型属于平面应变,古差异应力值介于30~40 MPa之间。长石-石英矿物温度计以及石英C轴EBSD组构指示剪切带以中低温变形为主,温度在400℃~500℃,属绿片岩相变质,具中-低温韧性剪切带特征。韧性剪切带内普遍存在变形分解现象,弱变形带内岩石残斑含量较高,眼球状构造和S-C组构较为发育;强变形带岩石残斑含量较低,剪切面理较为发育,糜棱面理发育较弱或者不发育。     

超高压榴辉岩中绿辉石组构和变形机制研究进展

榴辉岩中绿辉石晶格优选方位(LPO)类型主要有S型(压扁型)组构、L型(收缩型)组构、L-S中间型组构、退火型组构,其中L型和S型组构是绿辉石在超高压岩石中最发育的组构类型.矿物组构的产生与变形机制密切相关,目前还无法解释绿辉石LPO产生和变化的原因.对天然绿辉石变形机制的最新研究进行了评述,包括位错蠕变产生变形绿辉石LPO的传统观点,以及扩散蠕变伴随晶体各向异性生长和空间群转换两种新观点.使用费氏台对大别山双河地区榴辉岩中的绿辉石组构进行了测量,并用电子背散射衍射技术(EBSD)对测量结果进行了验证.结合榴辉岩的显微构造和绿辉石组构特征对大别山双河超高压榴辉岩中绿辉石的变形机制进行了初步探讨,认为其变形机制以位错蠕变为主.     

Fluid-assisted fracturing,cataclasis, and resulting plastic flow in mylonites from the Moresby Seamount detachment,Woodlark Basin

The Moresby Seamount detachment (MSD) in the Woodlark Basin (offshore Papua New Guinea) is a large active low-angle detachment excellently exposed at the seafloor, and cutting through mafic metamorphic rocks. Hydrothermal infiltration of quartz followed by that of calcite occurred during cataclastic deformation. Subsequent deformation of these a priori softer minerals leads to mylonite formation in the MSD. This study aims at a better understanding of the deformation mechanism switch from cataclastic to plastic flow. Deformation fabrics of the fault rocks were analyzed by light-optical microscopy. Rheologically critical phases were mapped to determine distributions and area proportions, and EBSD was used to measure crystallographic preferred orientation (CPO). Strong calcite CPOs indicate dominant dislocation creep. Quartz CPOs, however, are weak and more difficult to interpret, suggesting at least some strain accommodation by diffusion creep mechanisms. When quartz aggregates are intermixed with the polymineralic mylonite matrix diffusion creep grain boundary sliding may be dominant. The syntectonic conversion from mafic cataclasites to more siliceous and carbonaceous mylonites induced by hydrothermal processes is a critical weakening mechanism enabling the MSD to at least intermittently plastic flow at low shear stresses. This is probably a crucial process for the operation of low-angle detachments in hydrated and dominantly mafic crust.     

形变实验中的构造地球化学及对成矿的意义

通过对不同岩石，矿石样品进行的构造地球化学变实验结果表明，形变中形成了典型的塑性变形组构，同时也使样品中的矿物不仅发生形貌，颜色，干涉色以及结构的改变，而且矿物化学成分也发生了明显的变化，说明形变不仅是一种构造和地球化学作用过程，同时也是一种成矿作用。     

Geology, geochemistry and origin of the banded and granite gneisses in the basement complex of the Ilesha area, southwestern Nigeria

The basement complex in the Ilesha area consists of two distinct units — the gneisses and the schists. The Ilesha Schist Belt is a back-arc basin where there has been a subduction of an ocean slab into the mantle. This was followed by partial melting of mantle and ocean sediments to generate a wet basaltic magma, as revealed by spidergrams and REE fractionation patterns for the rocks in this belt. In this environment, differentiation of the wet basaltic magma led to the emplacement of a set of rocks, which formed a proto-continent. These rocks were then eroded to generate a sedimentary sequence which was metamorphosed into banded gneiss from which the granite gneisses were derived. The banded gneiss, characterised by alternation of felsic and mafic bands, is composed of medium to very coarse plagioclase, hornblende, quartz and biotite. The granite gneiss, composed of biotite, K--feldspars, quartz and minor garnet, occurs in close association with the banded gneiss.Chemical evidence revealed that elements that are depleted in the banded gneiss are concentrated in the granite gneiss and vice-versa; suggesting a petrogenetic link between these rocks.The schists were deposited as sediments composed of quartz, muscovite, biotite and Fe oxides. These sediments were metamorphosed to form quartzite schists which were folded into the gneisses. After the emplacement of these rocks, there was transpressive tectonic activity in this schist belt, causing deformation of these rocks, and emplacement of the northeast-southwest Ifewara-Zungeru Fault System, which separates the Ilesha Schist Belt into two halves.     

中国大陆显生宙俯冲型、碰撞型和复合型片麻岩穹窿(群)

片麻岩穹窿(gneiss dome)是中下地壳热动力学过程产生的、与岩浆作用(或混合岩化作用)密切相关的穹窿状构造。片麻岩穹窿大部分是地壳深层次变动的产物,在世界范围内几乎出露在所有的折返造山带中,反映了所在地区地壳的大幅度抬升。片麻岩穹窿核部主要是无或弱岩浆组构的花岗岩体和高级变质岩(例如混合岩),边部是具有岩浆组构的花岗片麻岩,幔部由来自地壳深部的高级片岩和片麻岩组成。片麻岩穹窿的形成经历从垂直上升的地壳流导致的岩浆上涌的挤压收缩机制到岩浆体侵位的顶部伸展机制的转化过程。根据片麻岩穹窿的岩石组合、组构特征、成因机制和大地构造背景以及片麻岩穹窿与地壳流关系的分析,结合中国大陆典型片麻岩穹窿的研究,提出中国大陆显生宙的片麻岩穹窿和片麻岩穹窿群可以划分为与大洋岩石圈板片俯冲增生与随后的折返造山相关的"俯冲型"片麻岩穹窿(群),如秦岭片麻岩穹窿;与陆陆碰撞折返造山有关的"碰撞型"片麻岩穹窿(群),如北喜马拉雅拉轨岗日片麻岩穹窿(群)和松潘甘孜雅江片麻岩穹窿(群);与俯冲和碰撞的叠合作用有关的"复合式"片麻岩穹窿(群),如帕米尔空喀山片麻岩穹窿和东冈底斯林芝片麻岩穹窿(群)。     

The transition between deformation regimes dominated by intercrystalline diffusion and intracrystalline creep evaluated by oxygen isotope thermometry

The dominant flow mechanism in tectonic processes depends on the rheological properties of geological materials and the physical conditions prevailing during deformation. We have evaluated the relative importance of intercrystalline diffusion and intracrystalline creep in crustal deformation in terms of temperature and grain size.Oxygen isotope thermometry has been used to elucidate the thermal environment obtaining during deformation and contemporaneous metamorphism of Dalradian rocks from Southwest Scotland. The temperature and grain size data, applied in conjunction with microstructural criteria for evaluating independent mechanisms of steady-state flow, allow recognition of a low-temperature deformation regime dominated by intercrystalline diffusion, and a high-temperature regime dominated by dislocation processes.The transition between the fields of intercrystalline diffusion and dislocation creep for quartz and calcite of 100 Mm grain size occurs at about 450° C and about 300° C, respectively. These empirically derived results are consistent with the temperature intervals over which intercrystalline diffusion and dislocation creep, respectively, are predicted to be dominant at geologically reasonable strain rates, as derived from theoretically formulated deformation mechanism maps for quartz and calcite.Grain growth may play an important role in delimiting the higher-temperature boundary of the intercrystalline diffusion field. Intercrystalline diffusion is the only deformation mechanism that involves mass transfer over distances that are large in relation to the grain size. This result has important consequences for geochemical transport phenomena.     

大陆俯冲隧道中的应变不均一分布：来自大别山超高压变质岩的记录

俯冲隧道是俯冲板片与上覆板块之间的剪切带,也是高压—超高压变质岩折返和深部流/熔体活动的通道。大别山超高压变质岩分布广泛,变形程度差异很大,是研究大陆俯冲隧道中岩石变质- 变形过程的理想地区。本文系统总结了前人对中大别双河地区超高压变质岩的岩石学和年代学研究成果,在双河地区开展了地质填图、应变分析和三维构造重建。通过将超高压变质岩的变形特征与P- T- t轨迹结合,识别出超高压变质岩折返过程中的三期韧性变形。在双河北部发现了一个上盘向NW剪切的千米尺度的榴辉岩相鞘褶皱,枢纽向SE倾伏,倾伏角约20°,与榴辉岩、片岩和长英质片麻岩的拉伸线理平行,表明超高压变质岩初始折返阶段的流体活动使榴辉岩的强度显著降低,榴辉岩与围岩一起发生韧性变形。该期变形被角闪岩相退变质阶段上盘向NW的剪切叠加,此时应变集中于片麻岩、片岩、大理岩等非能干层,强度较高的榴辉岩成为构造透镜体。而绿片岩相变质阶段上盘向SE方向的剪切与早白垩世北大别花岗片麻岩穹隆的形成有关。对双河南部弱变形花岗片麻岩的锆石U- Pb定年揭示了757±14 Ma的原岩年龄和 240~216 Ma的变质年龄,与双河北部含柯石英强变形花岗片麻岩类似,暗示其也经历了三叠纪超高压变质作用及随后的角闪岩相退变质作用。通过计算长英质片麻岩的有效黏度,发现无水碱长花岗片麻岩的有效黏度高于黑云斜长片麻岩,折返阶段的流体活动使超高压变质岩的强度显著降低,当局部的流体活动不足以弱化碱长花岗岩体时,应变集中于黑云斜长片麻岩。因此,大陆俯冲隧道中的应变分布受矿物组成、流体活动和岩体规模的共同影响。     

内蒙古大青山古元古代造山带中-下地壳深熔流变研究

内蒙古大青山地区是典型的早前寒武纪造山带根部岩石出露区,大量下地壳高级变质-深熔岩石中保留了丰富的流变构造样式,是开展部分熔融岩石流变行为研究的天然实验室。本文对内蒙古大青山地区雪海沟和大庙-忽鸡沟构造带内变形岩石开展了宏观、微观构造解析、EBSD组构以及锆石U-Pb年代学研究,并结合前人研究成果,考查了不同构造层次、不同熔融程度岩石的流变特征及其与造山过程的耦合关系。研究结果表明,雪海沟至大庙-忽鸡沟地区体现了造山带地壳结构层次由深至浅的特点。深部构造层次（雪海沟）高级深熔条件下,宏观上以各种形式的浅色脉体参与岩石流变,深熔熔体夹矿物颗粒流形成网状的断续条带状构造。微观上斜长石受扩散蠕变、颗粒边界滑移和颗粒流动影响,一般没有明显的晶内变形组构,CPO（晶格优选方位）发育不明显。在中深部构造层次（大庙-忽鸡沟）深熔作用相对较弱,宏观上形成平行片麻理的较规则条纹/条带构造。微观上斜长石发生位错蠕变,CPO发育明显。此外,角闪石在不同构造层次下均表现出位错蠕变特征,结晶优选方向受深熔作用影响不大。上述变形样式和机制,体现了造山带根部高级变质-深熔岩石在固-液两相介质中,发生水平层状粘-塑性流动变形特点。随后深熔岩石的塑性流动变形伴随加厚地壳的伸展减薄-隆升过程而逐渐硬化并遭受剥露。     

Granitoid rocks of the southern Menderes Massif (southwestern Turkey): field evidence for Tertiary magmatism in an extensional shear zone

Recent field campaign in the southern Menderes Massif in southwestern Turkey revealed that the so-called ‘core of the massif’ comprises two distinct types of granitoid rocks: an orthogneiss (traditionally known as augen gneisses) and leucocratic metagranite, where the latter is intrusive into the former and the structurally overlying ‘cover’ schists. These differ from one another in intensity of deformation, degree of metamorphism and kinematics. The orthogneiss display penetrative top-to-the-N–NNE fabrics formed under upper-amphibolite facies conditions during the Eocene main Menderes metamorphism (MMM), whereas foliation and stretching lineation exists in the leucocratic metagranites but are not strongly developed. The leucocratic metagranites show evidence of syn- to post-emplacement deformation in a series of weakly developed top-to-the-S–SSW fabrics formed under lower greenschist-facies (?) conditions. Leucocratic metagranite bodies occur all along the augen gneiss–schist contact in the southern Menderes Massif; they are emplaced as sheet-like bodies into country rocks (previously deformed and metamorphosed during a top-to-the-N–NNE Alpine orogeny) along a ductile extensional shear zone, located between orthogneisses and metasediments, which was possibly active during emplacement. The data presently available indicate that emplacement and associated ductile extensional deformation occurred during Late Oligocene–Early Miocene time. These results confirm previous contentions that there are Tertiary granites in this part of the Menderes Massif.