鲁西地区韧性剪切带岩石磁组构分析及其构造意义

岩石磁组构分析可用来研究岩石的组构特征及构造变形。鲁西地区韧性剪切带岩石磁组构具有磁各异性度Ｐ和磁百分率各向异性值Ｈ高、磁化率量值椭球呈压扁状、磁面理发育而磁线理不发育的特点。区内韧性剪切带变形强烈,以压扁作用为主,最大主压应力方向近ＮＥ和Ｓ－Ｎ向,以右旋运动为主。韧性剪切带形成以后,区内主要经历了热蚀变和脆性变形,韧性变形很弱     

鲁西地区韧性剪切带岩磁组构分析及其构造意义

岩石磁组构分析了可用来研究岩石的组构特征及构造变形。鲁西地区韧性剪切带岩石磁组构具有磁各异性度Ｐ和磁百分率各向异性值Ｈ高、磁化率量值椭球呈压扁状、磁面理发育而磁线理不发育的特点。区内韧性剪切带变形强烈,以压扁作用为主,最大主压应力方向近ＮＥ和Ｓ－Ｎ向,以右旋运动为主。韧性剪切带形成以后,区内主要经历了热蚀变和脆性变形,韧性变形很弱。     

北京怀柔崎峰茶-琉璃庙地区岩石磁组构特征及其构造意义

磁组构是指磁化率的各向异性。北京崎峰茶－琉璃庙地区岩石磁组构造特征是磁各向异性度Ｐ值、磁椭球扁率Ｅ＞０为主、磁面理发育而磁线理很差。本区构造变形强烈，以压扁变形为主，Ｓ－Ｎ向构造带是东盘上升、西盘下降，Ｅ－Ｗ向构造带是上盘由南向北逆冲。     

阿尔泰南缘东段变形岩石磁组构分析

磁组构是指岩石磁化率的各向异性,磁组构方法已经被广泛应用于构造变形分析。阿尔泰南缘东段地区岩石磁组构特征是磁各向异性度P值大,反映本区总体韧性剪切变形强烈。萨尔布拉克—科克萨依脆性劈理化带和玛因鄂博韧性剪压构造带的E>0占优势,磁面理发育,部分样品磁线理发育,反映变形以压扁变形为主,主压应力方向为NE(NEE)向,伴随弱的左行剪切;达拉维孜—阿热勒托别韧性流变构造带和锡泊渡—富蕴深层次变晶糜棱岩带E>0和E<0均存在,磁面理和磁线理均发育,反映以剪切变形为主;其中达拉维孜—阿热勒托别构造带主压应力方向为NE(NEE)向,为左行剪切,而锡泊渡—富蕴构造带主压应力方向为SN向,为右行剪切。在达拉维孜—阿热勒托别构造带中的哈腊苏铜矿和卡拉先格尔—老山口一带一些叠加蚀变矿化的强变形岩石的P值明显减小,说明在韧性变形之后发生过矿化热液作用导致磁化率各向异性发生了均一化。结合区域构造分析,可以认为萨尔布拉克—科克萨依构造带、达拉维孜—阿热勒托别构造带和玛因鄂博构造带构成一个完整的板块碰撞聚合带,而锡泊渡—富蕴构造带可能为在古生代期间被强烈改造的具有前震旦纪结晶基底的微大陆的残留(或断片)。     

广东河台金矿围岩磁组构特征、年代学及与金矿化关系

河台金矿田是目前粤西、桂东南已发现最大的金矿田,大部分矿体产出在剪切带糜棱岩中,是典型的与剪切带有关的金矿床。在构造研究上,前人只注重糜棱岩的构造分析工作,而忽视了同样作为矿体围岩的混合花岗岩和片岩的研究。目前为止,矿体围岩的形成时代、变质变形特征以及与成矿之间的关系尚不清楚。我们在野外观测、显微构造分析的基础上,对河台金矿的混合花岗岩和片岩展开了磁组构分析工作。岩石磁组构分析结果显示:样品的平均磁化率Κm值总体较小,顺磁性矿物主导了样品的磁组构;磁化率各向异性度P值均1.04,范围在1.044～1.648之间;磁化率椭球体形状参数T总体0;扁率E值多1,或接近于1;在弗林图解中,数据主要集中在压扁区,少部分有剪切特征;混合花岗岩最小磁化率轴的方位表明岩石受到的主压应力呈NNW-SSE或近S-N向;片岩的磁面理呈NE向,磁线理呈NW或NNW向近水平,反映岩石受到左行走滑导致的挤压或者韧性拉长变形的特征。磁组构特征总体反映出河台地区的岩石磁化率椭球体以压扁型为主,磁面理较磁线理发育,经历了较强烈的近SN向弥散性的挤压作用和局部韧性剪切变形。此外,河台金矿的混合花岗岩LA-ICP-MS锆石U-Pb年龄为251.7±1.7 Ma。在成矿过程中,岩石校正后的磁各向异性度Pj值与金属元素Au、Cu含量呈弱的负相关关系,说明岩石矿化蚀变作用晚于构造变形作用。结合各岩石的宏观片理、显微构造和前人的年代学工作,推测河台地区地质事件的早晚顺序依次是混合岩化→剪切变形→金矿形成。     

柴达木盆地西部新生界磁组构特征及其构造意义

柴达木盆地西部狮子沟一带新生代沉积岩磁组构分析结果显示, 岩石磁组构具有磁面理发育、磁线理不发育、磁化率量值椭球呈压扁状的特点; 磁化率各向异性度P值不大, 反映总体构造变形相对较弱。岩石磁组构反映的应力状态总体为以NE向挤压为主, 与轴向NW的背斜构造发育相一致。该区岩石磁组构大多具有原始沉积磁组构特征, 磁面理产状大体上反映沉积岩层的层理, 同时也记录了受NE向挤压作用的痕迹。根据岩石磁组构与地层层理之间的关系分析, 柴西地区两翼不对称的狮子沟背斜具有断展褶皱性质, 其形成与下部的花土沟逆冲断层向南西方向的仰冲有关。      

内蒙古察右后旗三道沟一带韧性剪切带磁组构特征及其构造意义

变形岩石的磁组构参数K1、K2、K3、P、T、F、L、E等可以用来定量地分析和了解构造变形的性状。笔者对分布于察哈尔右翼后旗三道沟一带的构造岩进行磁组构特征研究发现:E值多大于1,或接近于1;T值大于0的明显多于小于0的;P值均大于1,而以F和L的对数值为轴所作的变型弗林图解中数据主要集中在剪切区和压扁区。上述结果表明磁化率椭球体主要表现为磁面理较磁线理发育的压扁型椭球体,三道沟一带韧性剪切带的构造岩石经历了力学机制为挤压剪切的强烈构造活动。这种由磁组构揭示的应力应变特征得到了野外露头及显微构造的佐证。     

对磁组构在岩石变形分析应用中若干问题的思考

在应用传统的磁组构方法进行岩石构造变形分析时,发现这些方法中有许多不完善之处,如变形岩石磁化率量值椭球和应变椭球是否可以对应及对应条件,初始磁组构是否会影响变形碉石磁化率量值椭球与应变椭球的对应关系,岩石脆性破裂前的塑性变形是否影响磁组构,韧性变形如何影响磁组构,能否用磁组构来推断主应力方向,Ｒａｔｏｒｅ（１９８０）最小磁化率指向对韧性剪切带运动方向和方式的分析在多期变形区是否适用等,并据此提出解     

衡山岩体西缘韧性剪切带磁性组构研究

本文对采自衡山花岗岩体西缘韧性剪切带的标本进行了岩石磁性组构研究,并将其与常规应变分析方法所得结果予以比较,表明了岩石磁化率各向异性椭球体与应变椭球体之间有一定的对应关系,岩石磁化率各向异性技术可望成为构造地质学的一种新手段。岩石磁性组构资料可应用于变形岩石的应变分析,特别是在没有宏观应变标志或者通常的岩石组构分析方法太费时间的情况下更显出其优越性。     

西藏南部聂拉木地区前寒武纪岩石磁组构及其构造意义

通过对西藏南部聂拉木地区前寒武纪岩石磁组构进行研究表明:该区岩石磁化率百分率的各向异性H值较高,均大于10%,这说明岩石曾经历了较强烈的韧性变形。根据岩石最小磁化率从主轴K3方向推断的岩石变形期,最大的主压应力方位主要有SN向、NE-SW向、NW-SE向。岩石磁组构费林(Flinn)图解表明,大部分岩石磁组构具有磁面理发育、磁线理不发育,岩石磁化率量值椭球体呈压扁状的特点。部分岩石磁组构还具有磁线理发育、磁面理不发育,岩石磁化率量值椭球体呈拉长形的特点。因此,该区域构造应变型式具有压缩应变和拉伸应变二种型式。岩石磁组构研究还表明,该区具有SN向挤压、NW-SE向挤压、NW-SE向伸展滑脱三期构造应力。这说明高喜马拉雅结晶基底岩石曾经历了SN向逆冲推覆构造作用,NW-SE向逆冲推覆构造作用和NW-SE向伸展滑脱构造作用过程。构造应力场的转变及其构造作用,为印度板块与欧亚板块之间,自白垩纪末~始新世晚期发生的弧~陆、陆~陆碰撞,和始新世晚期以来,强烈的陆内汇聚造山与青藏高原剧烈隆升,及区域伸展滑脱构造作用过程的响应。     

桂北地区三门韧性剪切带的厘定及其构造意义

通过野外地质调查、室内显微组构分析和磁组构测量,在桂北三门地区厘定出一条大型韧性剪切带;并利用热液锆石U-Pb定年约束其变形时代.三门韧性剪切带发育密集的透入性片理、旋转碎斑系、拉伸线理、眼球构造、书斜构造、A型褶皱、波状消光、机械双晶、核幔构造和S-C组构等宏观和微观韧性变形特征.磁各向异性度（P值）显示其走向呈NNE向,倾向呈NWW向.运动学指向显示早期具有左旋逆冲剪切,晚期具有右旋正滑剪切的运动学性质.磁化率椭球体扁率（E值）显示岩石变形以压扁型应变为主,暗示运动学方向以左旋逆冲剪切为主.镁铁质糜棱岩的热液锆石U-Pb定年结果为441±2 Ma,代表三门韧性剪切带的变形时代.在磁组构、运动学和年代学研究的基础上,结合区域地质资料,认为该韧性剪切带是华南加里东期华夏陆块由SE向NW逆冲到扬子陆块受阻后反冲作用的产物.这一认识揭示了扬子陆块和华夏陆块碰撞拼合的方式和时代,为深化华南加里东构造运动的认识提供了新的资料.      

Structural geometry and kinematics of the Ailao Shan shear zone: insights from integrated structural,microstructural, and fabric studies of the Yao Shan complex,Yunnan, Southwest China

ABSTRACT

The Yao Shan complex, a massif near the southern segment of the Ailao Shan–Red River (ASRR) shear zone, bears important information on the structural framework of the massif and the kinematics of ductile shearing along the ASRR shear zone. In this contribution, structural, microstructural, quartz c-axis fabric, magnetic fabric, and geochronologic data are used to determine the structural framework of the Yao Shan massif and its tectonic implications for the ASRR shear zone. The Yao Shan complex is characterized by an overall linear A-type antiform that contains a core of high-grade metamorphic rocks with Palaeoproterozoic to Mesozoic protoliths and a mantle of Permo-Triassic low-grade rocks. Both the high-grade metamorphic core and low-grade Permo-Triassic rocks have experienced progressive ductile shearing. Anisotropy of magnetic susceptibility (AMS) results from 17 samples collected along the Xinjie–Pingbian section across the complex show that magnetic lineation (K_max) and foliation (K_max–K_int) are generally subparallel to the corresponding structural elements in the sheared rocks. The shape parameter E values of the magnetic ellipsoids are indicative of dominantly oblate and plane strain, but vary with protolith type and degree of strain among the various rock types. In agreement with the field and microstructural observations, the corrected degree of anisotropy (Pj) values reflect high shear strain in the core rocks and relatively low shear strain in the low-grade strata. A kinematic analysis based on structural and magnetic fabric data shows that both left- and right-lateral shear occurred during the deformation of the Yao Shan complex. Therefore, instead of being an element of the ASRR shear zone, the Yao Shan complex constitutes a crustal-scale inharmonic A-type fold with a fold axis parallel to the stretching lineation. Geochronologic data reveal that the folding occurred coevally with ductile shearing of the middle to lower crust between ca. 30 and 21 Ma.     

阿尔金北缘地区韧性剪切带型金矿床构造控矿解析

韧性剪切带型金矿是一种成矿机制与控矿因素都与韧性剪切带及其演化密切相关的金矿床类型。阿尔金北缘地区不同层次剪切带发育,金矿床受韧性剪切带控制明显,在区域上,韧性剪切带控制金矿床(点)的分布;在矿床范围内,韧性剪切带及其演化过程中形成的韧脆性剪切带既是唯一的赋(含)矿构造,也对矿化带、矿体的形态、产状、规模及分布起决定性的控制作用;压扭性韧性剪切变形特点决定了金矿化类型以蚀变糜棱岩型为主,交代蚀变作用发育。含矿构造裂隙以P型为主,少量D型和R型,个别为R~1型和T型;构造变形所引发的动力分异作用及其形成的动力变质热液是金矿成矿流体的主要来源之一,这与地球化学和成矿流体包裹体研究显示的大平沟金矿床成矿物质主要来源于变质岩、成矿流体有相当部分来源于变质水的特征相吻合。结合糜棱岩磁组构研究,发现磁各向异性度P值与金元素含量呈负相关关系,说明构造变形早于金矿化蚀变作用,这种时序关系进一步佐证了韧性剪切带型金矿床的成矿模式。即大面积的韧性变形构造动力分异作用形成的含金热液不是就地原位矿化,而是向上迁移并集中到范围比较窄小的韧-脆性或脆性裂隙中才发生金元素富集,最终形成金矿床。     

Strain distribution within a km-scale,mid-crustal shear zone: The Kuckaus Mylonite Zone,Namibia

The subvertical Kuckaus Mylonite Zone (KMZ) is a km-wide, crustal-scale, Proterozoic, dextral strike-slip shear zone in the Aus granulite terrain, SW Namibia. The KMZ was active under retrograde, amphibolite to greenschist facies conditions, and deformed felsic (and minor mafic) gneisses which had previously experienced granulite facies metamorphism during the Namaqua Orogeny. Lenses of pre- to syn-tectonic leucogranite bodies are also deformed in the shear zone. Pre-KMZ deformation (D₁) is preserved as moderately dipping gneissic foliations and tightly folded migmatitic layering. Shear strain within the KMZ is heterogeneous, and the shear zone comprises anastomosing high strain ultramylonite zones wrapping around less deformed to nearly undeformed lozenges. Strain is localized along the edge of leucogranites and between gneissic lozenges preserving D₁ migmatitic foliations. Strain localization appears controlled by pre-existing foliations, grain size, and compositional anisotropy between leucogranite and granulite. The local presence of retrograde minerals indicate that fluid infiltration occurred in places, but most ultramylonite in the KMZ is free of retrograde minerals. In particular, rock composition and D₁ fabric heterogeneity are highlighted as major contributors to the strain distribution in time and space, with deformation localization along planes of rheological contrast and along pre-existing foliations. Therefore, the spatial distribution of strain in crustal-scale ductile shear zones may be highly dependent on lithology and the orientation of pre-existing fabric elements. In addition, foliation development and grain size reduction in high strain zones further localizes strain during progressive shear, maintaining the anastomosing shear zone network established by the pre-existing heterogeneity.     

The Ductile Deformation Characteristics of Caledonian Intracontinental Orogeny in the Northeastern Jiangshan-Shaoxing Tectonic Zone: Insights from Magnetic Fabric Study and Its Geodynamic Implication

The Jiangshan-Shaoxing tectonic zone was the northeastern boundary between the Yangtze Block and the Cathaysia Block during the Neoproterozoic and was an intracontinental orogenic belt during late of the early Paleozoic. In this tectonic zone, there develops a lot of mylonite underwent strong ductile deformation and schist, gneiss, and amphibolite with medium and high grade metamorphism which was formed during the late of early Paleozoic. The research of geometry and kinematic of ductile deformation in Jiangshan-Shaoxing tectonic zone is very important to reveal the tectonic process of intracontinental orogeny. This paper uses the anisotropy of magnetic susceptibility (AMS) to determine the ductile deformation geometry and kinematic of Jiangshan-Shaoxing tectonic zone combing with the field survey. In this study, 190 specimens of 19 locations and 221 specimens of 23 locations from Wangjiazhai section and Lipu-Sizhai section were analyzed. The magnetic foliation over magnetic lineation in both Wangjiazhai and Lipu-Sizhai sections together with the field observations indicated a compressional deformation pattern. 3 and 4 strong ductile deformation zones can be established in the Wangjiazhai section and the Lipu-Sizhai section, respectively. According to the magnetic fabric and petro-fabric studies, the Northeastern Jiangshan-Shaoxing tectonic zone suffered two kinds of deformation patterns during the late early Paleozoic, i.e., the thrusting deformation followed by sinistral shear deformation.     

湖北青峰韧性剪切带构造岩的磁性组构研究

通过对青峰韧性剪切带中糜棱岩的磁性组构研究,同时与常规主应变分析方法所测结果比较,表明岩石磁化率各向异性椭球体与应变椭球体之间有一定的对应关系。磁性组构的特征为构造岩变形机制,以及断裂带的运动学、动力学等的研究提供了一种比较可靠、准确、方便的方法。     

Magnetic fabric study across the Ailao Shan–Red River shear zone

The anisotropy of magnetic susceptibility (AMS) of 351 specimens from 51 sites across the Ailao Shan–Red River shear zone (ASRR) was measured to determine its magnetic fabric. Rocks range westward from core schistose gneiss, through low-grade schist, to Triassic sediment. Magnetic ellipticity analysis shows that 41 of 51 sites have an oblate compressional fabric and the other 10 sites have a prolate fabric. P_J value drops by 22.4% in the low-grade schist and by 27.4% in the Triassic sediment on average with respect to the gneiss, suggesting a rapid decrease of deformational intensity. The directions of principal susceptibilities are closely related to the deformation of the Ailao Shan–Red River shear zone. The susceptibility plane always coincides with the schistosity or cleavage plane. Most of the maximum susceptibility axes trend NW–SE. In the shear zone, the maximum susceptibility axes (K_max) are parallel to the lineation within the foliation plane. With increasing distance from the shear zone, there is a trend that they become parallel to the down-dip of reverse faults or cleavage. This indicates changes in deformation mode, inside and outside the shear zone. Within the shear zone, horizontal movement is dominant. Outside, shortening prevails. The overall minimum magnetic axes align NE–SW with subhorizontal to low dip angles, suggesting that the dominant shortening is NE–SW directed. Caution should be exercised when AMS is used to determine shear sense in strong shear zones because the angle between the minimum susceptibility axis (K_min) and pole of foliation is small, and also because the attitude of foliation varies from place to place. They result in unreliable or even wrong shear sense. Another important result is the axial ratio of magnetic susceptibility ellipsoid along the study section. With these data, it is possible to establish an axial ratio relationship between the finite strain ellipsoid and magnetic susceptibility ellipsoid for quantitative calculation of offset.