滇西澜沧江构造带中-南段澜沧群变质变形期次及Ar-Ar年代学约束

澜沧群变质变形过程的厘定有助于揭示澜沧江构造带的演化历史.通过对双江-惠民地区出露的中-低绿片岩相变质岩系与高压变质岩系的"构造-变质"双重解析,发现澜沧群变质岩系:（1）以挤压体制下的褶劈理S₂为区域性面理,浅变质岩系中石英脉条带代表的面理S₁与层理S₀产状一致,并在第2期强烈压扁后与S₂近平行;（2）构造样式与变质变形期次在研究区域内基本一致,表现为二叠纪-三叠纪两期次中深构造层次透入性变形为侏罗纪-新生代浅-表层次变形所叠加;（3）高压变质岩记录了两个期次的深层次构造变形,电气石与石榴石变斑晶具有明显的两阶段生长模式,核部（M_1aD_1a）可能代表了峰期榴辉岩相变质作用,边部代表折返过程中的蓝片岩相（M_1bD_1b）阶段.高压变质岩与浅变质岩第2期（M₂D₂）构造层次及变形样式一致,代表折返后的挤压拼贴过程,两者的剪切型褶劈理S₂均指示上盘S向的剪切滑动.结合新生代三江地区发生的近90°块体旋转,恢复第2期为上盘指向E的逆冲剪切作用.通过对幸福变质石英砂岩白云母、小黑江多硅白云母和蓝闪石的40Ar-39Ar定年,以及对前人小黑江蓝闪石40Ar-39Ar年龄的重新解释,共厘定出澜沧群4个构造阶段:（1）高压变质岩第1期晚期（D_1b）蓝片岩相变质作用（~250 Ma）;（2）第2期（M₂D₂）中层次挤压（215~214 Ma）;（3）浅变质岩系第3期早期（D_3a）N-S向纵弯褶皱（111.9~103.7 Ma）与晚期（D_3b）逆冲（~82.28 Ma）;（4）第4期近E-W向纵弯褶皱（新生代,很可能晚于59.18 Ma）.      

西藏南冈底斯叶巴火山弧的构造-地层属性及其演化

南冈底斯岩浆岩带出露的一套早—中侏罗世火山-沉积建造经历了多期构造变形,致使这套火山-沉积层序发生了强烈的面理置换,形成了典型的构造-岩石地层。依据造山带地层划分方法将叶巴火山弧厘定为叶巴岩群,并根据内部岩性组合特征和构造变形特征将其进一步划分为邦堆岩组、叶巴岩组、甲玛岩组。运用构造解析原理划分了3期构造变形事件。第一期构造变形为脆-韧性剪切变形,剪切方式为纯剪占优的一般剪切变形,透入性面理S₁普遍置换层理S₀(S₁∥S₀),伴生倾伏向85°~100°陡倾的拉伸线理,运动学指示顶面朝西运动,存在左行和右行两个方向的剪切旋转碎斑共存的现象;EBSD实验结果显示变形的温度≤380 ℃,石英颗粒细粒化明显,重结晶方式为亚颗粒旋转重结晶;⁴⁰Ar-³⁹Ar年代学结果表明该期构造变形时代约为79 Ma,其可能代表新特提斯洋板片低角度(平板式)俯冲引起在弧后挤压背景下形成的挤出构造。第二期构造变形表现为S₁面理发生纵弯褶皱变形形成的轴面劈理S₂,轴面产状倾向北或南,倾角40°~70°,枢纽向西或北西西倾伏;结合区域地质演化特征,认为其可能是在晚白垩世(79~68 Ma)南北向持续的挤压应力条件下,南冈底斯弧后盆地整体向上挤出,引发上地壳缩短、加厚进而导致褶皱作用的发生。第三期主要为浅层次膝折构造和近东西向正断层,最大主压应力方向为铅直向,最小主压应力方向(伸展方向)为近南北向;结合区域构造演化特征,认为该期变形可能代表渐新世末—中新世初期(23.74~21.1 Ma),印度岩石圈或青藏高原岩石圈或两者组合的拆沉作用引起冈底斯岩基隆升(主要动力学机制)和GCT活动并共同作用导致近南北向伸展滑覆事件发生。     

江苏东海CCSD主孔超高压变形与折返变形的叠加关系

位于苏鲁超高压变质地体南部的中国大陆科学钻探工程（CCSD）主孔岩石经历了超高压变形及多期折返变形。第一期折返变形为伸展折返变形,榴辉岩发生角闪岩相退变质作用,没有新生面理或线理的发育,基本保留了超高压阶段的S-L组构,并有显示熔融体特征的强退变榴辉岩发育。第二期折返变形为SEE-NWW向挤压折返变形,超高压变形期形成的不同岩石类型在本期变形中表现出不同的叠加变形现象,榴辉岩类岩石早期形成的S倾面理主体部分转为SEE倾,但拉伸线理产状与超高压变形期的近SN走向基本一致,反映早期面理沿NNE轴向的重褶作用,局部又被向SEE缓倾的韧性剪切带切割;而片麻岩类岩石在超高压变形期形成的S-L组构的主体部分已被新生成的总体向SEE缓倾的S-L组构置换,反映早期面理不仅重褶,而且大部分再度发生韧性剪切变形,具SEE向NWW的逆冲剪切指向,矿物普遍重新定向。第三期折返变形发育具NWW向SEE正滑剪切指向的韧性剪切带,并伴随大量“Z”型褶皱构造的发育。第四期折返变形以NWW向SEE正滑的张性或张扭性脆性断裂活动为主。探讨了苏鲁超高压变质地体折返变形的力学机制及CCSD主孔岩石面理变化的形成机制。     

湖南渣滓溪锑钨矿区变形序列、成矿时代及含矿构造属性

渣滓溪锑钨矿床位于雪峰弧形构造带的中段,经历了早期钨矿、晚期锑矿等两期成矿作用。目前该矿床锑矿的成矿时代不明,控矿构造的形成背景也缺乏研究。鉴此,本文对渣滓溪矿床及外围地区开展了大量的地表露头和井下巷道的构造观测和解析,结合构造演化背景和区域构造特征,厘定了构造变形序列、钨矿和锑矿形成的时代背景以及含矿断裂的性质和形成时代,形成以下主要认识:(1)研究区自早至晚经历了6期主要变形事件:(1)志留纪晚期受到NW-NNW向挤压,形成NE-NEE向的褶皱、逆断裂及顺层剪切断裂;(2)中三叠世晚期受到NW-NNW向挤压,形成NE-NEE向的褶皱、逆断裂、逆冲剪切破裂和破劈理, NWW-NW向右行走滑断裂和剪切破裂, SN向左行剪切破裂, NNW向张节理等;(3)晚三叠世受到SN向挤压,形成NNE向左行剪切破裂、NE向左行走滑兼逆冲剪切破裂、NNW向右行剪切破裂和小断裂、SN向张节理等;(4)中侏罗世受到NWW向–近EW向挤压,形成NNE向褶皱、NEE-EW向右行走滑断裂和剪切破裂、NWW-NW向左行走滑断裂和剪切破裂;(5)早白垩世受到区域NW-SE向伸展,形成NE向正断裂;(6)古近纪中晚期...     

中国阿尔泰南缘构造变形层次与变形序列

中国阿尔泰造山带发育了一套被认为是早古生代的变质岩系,保留了原始成分层理S₀。岩石在下-中地壳层次经历了塑性变形及最深达到角闪岩相变质作用的改造。通过对岩石构造层次及变形序列分析,在造山带南缘识别出由深至浅、由早到晚发育的4个构造层次的变形样式,分别为流变构造、韧性剪切构造、褶皱劈理构造和断裂节理构造。流变构造以轴面NW走向、枢纽近直立的流动褶曲和NW走向近直立片麻岩面理为特征,局部发育长英质和镁铁质矿物分异条带,相当于下构造层次变形（约15～18 km）。韧性剪切构造以NW-NNW向和NNE-NEE向近直立的糜棱岩面理和片理面为特征,相当于下-中构造层次变形（约8～12 km）。褶皱劈理构造对应轴向NW、枢纽近水平的等厚褶皱、NWW和NNW向近直立劈理的产出,为中-上构造层次变形（约5～8 km）。上构造层次的断裂、节理构造在造山带南缘广泛发育,变形深度约浅于3～ 4 km。根据变形几何学、运动学关系及变形次序,确认它们是3期构造应力场作用的结果。在二叠—三叠纪,阿尔泰经历NE向（47°～55°）挤压应力场,在下-中构造层次发育317°～325°走向的流动褶皱、片麻理构造S_1-1,306°～308°走向左行和328°～332°走向右行近直立韧性剪切面理S_1-2,290°～295°走向左行和350°～355°走向右行、近直立片理面S_1-3。在古近纪NW向挤压应力场下,中-上构造层次发育20°～22°走向左行和78°走向右行片理面S_2-1,10°～20°和70°～78°近直立脆—韧性剪切面S_2-2和5°～8°压扭性断裂构造S_2-3。新近纪近N-S向应力场下,在浅地壳层次产出320°～325°和340°～345°走向右行走滑断裂,NWW向破劈理和NE向节理构造S₃。下构造层次变形被中-上构造层次变形叠加改造,体现变形深度层次与变形序列的一致性,反映了同构造挤压期的地壳抬升现象。     

勉略构造带构造变形过程及其地质意义

勉略构造带是印支期华北板块与扬子板块碰撞,并叠加后期陆内变形作用形成的复杂蛇绿构造混杂岩带,勉略构造带的形成演化对全面理解秦岭造山带构造演化具有非常重要的研究意义.本文以勉略构造带广泛发育的褶皱、断裂等构造现象为研究对象,通过详细的构造解析和古应力反演,揭示出勉略构造带经历三期构造变形:D1期变形为NW-SE向挤压,以发育轴面直立的紧闭同斜褶皱和高角度逆断层为特征,形成于早—中三叠世华北与扬子两大块体碰撞阶段;D2期变形为NE-SW向挤压,主要发育左行走滑剪切变形,叠加于早期构造形迹之上,构造带内普遍发育东西向近水平拉伸线理,局部发育倾竖褶皱,形成于晚三叠世—中侏罗世,该阶段秦岭造山带由早期的碰撞转为陆内变形,沿东西向断裂带发生大规模左行走滑;D3期变形为N-S向挤压,在晚侏罗世—白垩纪多向汇聚构造体制下,勉略构造带受南北向挤压,形成一系列共轭剪切断裂,该期断裂切割前两期构造变形,区域上表现为北侧的大巴山、西秦岭向南逆冲推覆,扬子北缘沿米仓山一带向北楔入秦岭造山带,形成向南突出的大巴山弧形逆冲推覆构造带、西秦岭武都-舟曲弧形构造带和一系列北东、南西走向的共轭剪切断裂系.     

黔西北五指山地区叠加构造变形特征对铅锌矿成矿的控制

五指山铅锌矿区位于贵州省普定县与织金县交界区域,大地构造位于扬子板块中部、江南造山带西缘。野外构造研究表明,受早古生代加里东构造运动的控制与影响,矿区内震旦系—下古生界构造变形与上古生界—中生界的构造变形明显不同。震旦系—下古生界构造线近东西向,发育近东西向平缓褶皱、南倾或北倾劈理,显示近南北向的挤压收缩变形。震旦系—下古生界区内发育两组南北、北西向陡倾断层,断层明显受限制而不穿越晚古生代之后的地层。发育在震旦系—下古生界内的层间滑动与断层活动控制着铅锌矿的分布。晚古生代之后区域构造应力场发生转变,由早期近南北向的挤压收缩转为早燕山期SEE向NWW挤压逆冲,由此对震旦纪—早古生代变形进行叠加与改造,宏观上形成以NE走向为特征的区域构造格局。后期形成的褶皱轴面主要向SEE倾斜,断层向NWW逆冲,与早期变形呈斜跨式叠加。燕山期断层活动促进了铅锌矿的迁移与聚集。     

湘中古台山金锑矿床变形序列、成矿事件及控矿构造

湘中古台山金锑矿位于雪峰构造带西南段东北部,发育SN向金矿脉和NW向金锑矿脉2类矿脉。前人提出SN向和NW向断裂为容矿构造,并获得了印支期成矿的⁴⁰Ar-³⁹Ar同位素年龄,但对容矿断裂的性质、形成时代以及2类矿脉的时代关系缺乏研究和认识。鉴于此,文章通过地表和井下露头构造以及矿化蚀变的观测、解析,结合区域构造特征、区域构造演化和测年资料等,厘定了古台山金锑矿区构造变形序列及其时代、不同类型矿脉的成矿时代和构造背景,探讨了构造控矿规律及动力机制。主要认识如下：(1)研究区自早至晚经历了5期主要变形事件：志留纪晚期受到NWW向挤压,形成NNE向板劈理、NNE向褶皱(水车背斜)、SN向顺层断裂、逆冲剪切破裂和断裂;中三叠世晚期受到NNW向挤压,局部形成NEE向轴面劈理;晚三叠世受到SN向挤压,形成EW向褶皱、NW向—NNW向右行走滑断裂和剪切破裂、NNE向左行走滑断裂和剪切破裂、EW向逆冲剪切破裂等;中侏罗世晚期受到NWW向挤压,形成EW向右行剪切破裂和断裂;古近纪中晚期受到NE向—NNE向挤压,形成SN向—NNE向右行剪切破裂和断裂、EW向—N...     

江南东段地区NE-SW向断裂带断层滑移矢量反演及其大地构造意义

华南中-新生代构造演化受太平洋构造域和特提斯洋构造域的联合控制.以江南东段NE-SW向景德镇-歙县剪切带和球川-萧山断裂中发育的脆性断层为研究对象,利用野外交切关系和断层滑移矢量反演方法厘定了7期构造变形序列并反演了各期古构造应力场,讨论了断层活动的时代及其动力学.白垩纪至新生代研究区7期古构造应力场分别为:(1)早白垩世早期(136～125Ma)NW-SE向伸展;(2)早白垩世晚期(125～107Ma)N-S向挤压和E-W向伸展;(3)早白垩世末期至晚白垩世早期(105～86Ma)NW-SE向伸展;(4)白垩世中期(86～80Ma)NW-SE向挤压和NE-SW向伸展;(5)晚白垩世晚期至始新世末期(80～36Ma)N-S向伸展;(6)始新世末期至渐新世早期(36～30Ma)NE-SW向挤压和NW-SE向伸展;(7)渐新世早期至中新世中期(30～17Ma)NE-SW向伸展.结合区域地质研究表明,第1期至第4期古构造应力场与古太平洋构造域的板片后撤、俯冲以及微块体(菲律宾地块)间的碰撞作用有关;第5期伸展作用受控于新特提斯构造域俯冲板片后撤,而第6期和第7期古构造应力场主要与印-亚碰撞的远程效应有关.白垩纪至新生代,华南东部受伸展构造体制和走滑构造体制的交替控制.先存断裂的发育可能是导致华南晚中生代走滑构造体制的主要控制因素.     

龙门山南段盐井-五龙断裂磁组构特征及其对几何学、运动学的制约

盐井?五龙断裂是龙门山中央断裂北川?映秀断裂的南延部分,也是龙门山南段的三大控制性主干断裂之一。为了详细认识盐井?五龙断裂的构造几何学、运动学特征,在野外构造研究的基础上,运用磁组构方法对盐井?五龙断裂105块构造岩定向样品进行深入研究。野外构造解析表明断裂至少发生了韧性挤压剪切、脆?韧性逆冲和脆性挤压碎裂三期构造变形。磁组构研究显示构造岩磁组构样品的平均磁化率k_m值具有强磁化率和弱磁化率两种特征。磁组构形状参数T、磁面理F值、磁线理L值和T-P_J图解显示磁化率椭球体主要为压扁型,磁面理较磁线理发育,局部发育较强磁线理,进一步表明盐井?五龙断裂以挤压、剪切为主,伴有拉伸变形的整体特征,样品的P_J整体较大,显示出构造强变形磁组构特征。最小磁化率主轴K_min方位表明盐井?五龙断裂北段和南段分别受到了NW-SE向和NEE-SWW向的挤压作用;K_min方位和倾伏角表明北段晚一期的脆韧性变形主体为自NW向SE的较高角度的挤压逆冲剪切变形,局部伴有极小量的左行走滑特征。断裂南段早期韧性变形整体以自SWW向NEE的挤压逆冲剪切变形为主,上盘(西盘)远离主干断裂表现为左行走滑兼逆冲的运动学特征,下盘变形主要以逆冲剪切变形为主,走滑分量极小,并且自西向东韧性剪切变形具有相对强弱相间的特征。     

Regional slaty cleavage formation and fold axis rotation by re-use and reactivation of pre-existing foliations: the Fiery Creek Slate Belt, North Queensland

A deformation history, comprised of six separate deformation events of differing intensity, has affected the rocks of the South Palmer River region of the the Hodgkinson Province, north Queensland. Within this region, a zone of pervasive slaty cleavage, herein termed the Fiery Creek Slate Belt, has developed as a result of the superposition of fabrics formed during several of these events. The most important processes in the formation of this composite cleavage were the re-use and reactivation of the favourably oriented, steep, N-S-trending S₂ foliation by the intense fourth deformation event, D₄. This produced micro-, meso- and macroscopic folds in an originally shallow S₃ foliation, produced during the intervening D₃ deformation, with an axial planar S₂–S₄ foliation. The D₄ stretching lineation, L⁴₄, plunges subvertically to steeply north and indicates that shear during D₄ was oriented steeply north-south. In the Fiery Creek Slate Belt, D₂ fold axes are interpreted to have formed in much shallower orientations than their present moderately N-S-plunging to subvertical orientations. We consider this to be a result of D₄ shear, which caused variable degrees of rotation of D₂ fold axes toward the D₄ stretching lineation due to subparallelism of the bulk shortening directions of the D₂ and D₄ events. Near-total destruction of the pre-D₄ foliations during slaty cleavage formation has produced a misleading impression of a simple deformation history. There is no relationship between metamorphic grade and intensity of slaty cleavage development.     

Deformation History of the Kunavaram Complex, Eastern Ghats Belt, India: Implications for Alkaline Magmatism Along the Indo-Antarctica Suture

The Kunavaram alkaline complex is a NE-SW trending elongate body located along a major lineament, the Sileru Shear Zone (SSZ) that is regarded as a Proterozoic suture related to Indo-Antarctica collision. The complex is hosted within migmatitic quartzofeldspathic gneisses, mafic granulites retrogressed to amphibolites, and quartzites. The structural evolution of the country rocks and the alkaline complex are similar. The first phase of deformation, D₁, produces a pervasive segregation banding (S₁) in all rock units within and outside the complex. A second deformation phase D₂ isoclinally folded S₁ along subvertical axial planes with shallow plunging axes. F₂ isoclinal folds are ubiquitous in the country rocks and the eastern extremity of the complex. In the interior of the alkaline body, D₂ strain decreases and S₁ is commonly subhorizontal. While amphibolite to granulite facies conditions prevailed during deformation, post-D₂ annealing textures testify to persisting high grade conditions. In the west, a NNE-SSW trending dextral shear zone with strike-slip sense (D₃) truncates the complex. Within this shear zone, quartzofeldspathic country rocks are plastically deformed, while hornblende-K-feldspar assemblages of the complex are retrogressed to biotite and plagioclase. Warping related to D₃ shears also resulted in fold interference patterns on the subhorizontal S₁ foliation in low D₂ strain domains. Based on its steep dip, north-easterly trend, and non-coaxial nature with dextral strike-slip sense, the D₃ shear zone can be correlated with the SSZ. Since this shear zone, i.e., the SSZ, is not associated with primary igneous fabrics and resulted in solid state deformation of the complex, it cannot be considered as a conduit for alkaline magmatism, but is probably responsible for the post-tectonic disposition of the pluton.     

Multiple Foliations Defined by Different Sillimanite Crystal Habits, Partial Melting and the Late Metamorphic Development of the Cannington Ag-Pb-Zn Deposit, Northeast Australia

A succession of foliations defined by different sillimanite-bearing structural fabrics suggests that the macroscopic, isoclinal synform that dominates the geometry of the Cannington Ag-Pb-Zn deposit, northwest Queensland, Australia formed during D₂. The five foliations in this succession, S₁ to S₅, are defined by aligned sillimanite with habits ranging from individual crystals in S₁ through S₄ to clusters of fibrolite in S₅ in both the matrix and as inclusion trails within garnet and gahnite (Zn-rich spinel) porphyroblasts. S₁, S₃ and S₅ formed as sub-horizontal foliations, whereas S_1a, S₂ and S₄ formed sub-vertically. Foliation intersection/inflexion axes (FIAs) within garnet and gahnite porphyroblasts preserve a succession of trends that shifts from W-E to N-S. This succession indicates that this region experienced N-S followed by W-E bulk crustal shortening. N-S shortening occurred during D₁and D_1a, and W-E shortening occurred from D₂ to D₅. Prismatic and rhombic sillimanite produced during D₁-D₄ accompanied prograde metamorphism to ca. 634 62°C and 4.8 1.3 kbar. The coexistence of fibrous, prismatic and rhombic sillimanite resulted from post peak metamorphic reactivation of the early foliations during D₅. The synformal D₂ fold was intensified during D₄ by W-E bulk shortening. Local partial melting occurred after D₁ in the appropriate bulk rock compositions, based on calculation of P-T pseudosections in the chemical systems KFMASH, KFMASHTO, NCKFMASH and MnNCKFMASH. Zn mineralization related to gahnite growth occurred during D₃ through D₄, and was redistributed by partial melting into structural and rheological sites during D₄ and D₅shearing.     

基于断层滑动数据反演的燕山中西段晚中生代古构造应力场:对华北克拉通破坏峰期应力状态的启示

在燕山中西段晚中生代岩体中的116个观测点中共采集到2 321组断层和破裂面滑动数据,利用Tensor软件进行古构造应力状态反演。将反演结果与区域构造变形及构造演化过程研究结果相结合,发现研究区在侏罗纪末-白垩纪初以来存在5期可识别的构造应力场:(1)晚侏罗世末-早白垩世初近N-S向挤压应力场(D1,148~127 Ma);(2)早白垩世NW-SE向挤压应力场(D2,143~127 Ma);(3)垂向挤压主导的多向水平伸展应力场(D3,120~110 Ma);(4)NE-SW向挤压(D4);(5)E-W向挤压的应力场(D5)。D1和D2可能分别与蒙古-鄂霍茨克洋消减关闭作用的远程构造效应,以及古太平洋板块向欧亚大陆板块下的俯冲作用有关,且这两大构造系统在该时期可能同时作用于燕山地区。D3期应力场可能反映源自壳下深部地幔活动引起的垂向挤压动力作用。D4、D5期应力场相对较弱,其动力学背景尚待今后研究进一步分析。本区古构造应力场研究结果表明,华北克拉通破坏峰期期间,主要的伸展作用并不完全符合西太平洋板块后撤主导的被动伸展裂谷模型,而是表现为深部地幔活动引起的垂向挤压作用主导的水平方向多向伸展。     

柴北缘二郎洞地区L 构造岩变形特征及其地质意义

柴北缘二郎洞地区出露包含早古生代岩石组合的达肯大坂岩群,其构造变形期次和变形时代研究接近空白, 本文首次在其中发现了面理微弱, 而拉伸线理十分发育的L 构造岩,对其详细的构造解析对认识柴北缘构造演化具有重要意义。二郎洞达肯大坂岩群存在两期构造变形作用（D₁、D₂）,D₁ 期变形表现为兼具逆冲分量的左旋走滑剪切,D₂ 期变形表现为兼具正断性质的右旋走滑剪切。D₁ 期变形产生LS 构造岩和L 构造岩。其中L 构造岩中矿物拉伸线理的倾伏向约为142°,与柴北缘造山带延伸方向一致,倾伏角一般在2°～54°。对L 构造岩以及侵入其中的未变形次安山岩进行LA-ICP-MS 锆石U-Pb定年,获得它们的结晶时间分别为457 Ma 和406 Ma,L 构造的变形时代可能介于457～406 Ma 之间。根据长石、石英等矿物的变形形式,估计L 构造岩的变形温度在380 ℃～420 ℃之间, 应形成于地下13～14 km 深处。在构造特征分析和岩相学研究的基础上,结合柴北缘早古生代岩浆活动时代构架,我们认为二郎洞地区L 和LS 构造岩的原岩可能是原特提斯洋向北俯冲增生过程中形成的早古生代弧花岗岩,由于柴达木-东昆仑板块和祁连陆块之间的斜向碰撞,导致局部地区出现挤压并沿造山带延伸方向走滑活动。在走滑剪切作用下使地壳流变层中的弧岩浆岩体向地表挤出,局部成分相对均匀的花岗质岩石,因具有较强的岩石力学性能而形成了L构造岩。     

广西南丹泥盆纪缺氧盆地沉积模式及其演化

根据Rhoads-Morse-Byers缺氧盆地生物相模式.同时考虑水体深度,将缺氧盆地沉积自上而下划分为充氧带、弱氧带和无氧带,与之相应的生物带则为喜氧生物带、贫氧生物带和厌氧生物带,按照这种模式,着重描述了广西南丹泥盆纪缺氧盆地的沉积特征及生物群特征。其演化大致经历了（1）充氧沉积-喜氧生物群阶段（D₁1）;（2）弱氧沉积-贫氧生物群阶段（D₁2-D₂）;（3）无氧沉积-厌氧生物群阶段（D₃1）;（4）弱氧沉积-贫氧生物群阶段（D₃2）。     

都龙-Song Chay变质穹隆体变形与构造年代——南海盆地北缘早期扩张作用始于华南地块张裂的证据

南海盆地的扩张经历了早期(中生代晚期至新生代早期)和晚期(32~17Ma)2个快速阶段,但2阶段在时间上相继,在形成机制上也可能是一致的.然而由于南海盆地与周围板块侧向作用的关系复杂,对扩张机制的认识一直极具争议,新的构造分析和测年资料表明“弧后扩张”及“走滑扩张”模式均与事实有出入.对位于华南地块西南缘的都龙SongChay变质穹隆体的研究表明,在中生代至新生代时期,至少经历了2期重要的伸展构造: D₁期(237~228Ma)穹隆的隆升与表露阶段,代表了印支期造山作用前的伸展构造; D₂期(86~78Ma)叠加和改造阶段,并有可能始于176~146Ma,致使穹隆进一步隆升和表露.D₂期构造在发育时间、伸展方向及变形方式等上既与华南地块同时期区域伸展构造特征相一致,也与南海盆地北缘早期扩张特征相一致.因此,作为华南地块的组成部分,南海盆地北缘的早期扩张也是华南中生代晚期至新生代早期伸展构造的构成部分.由此推测,南海盆地扩张的动力学机制可能主要来自于华南地块的板内变形作用,而哀牢山-红河断裂带的左行走滑作用对南海盆地新生代的扩张起到推动和加强作用.      

Correlations between metamorphic events and Rb-Sr ages in metasediments and eclogite from Western Tasmania

The Strathgordon area of low metamorphic grade (450±50°C, 4±1 Kb) and the eclogitebearing Lyell Highway-Collingwood River area, which is of higher grade (670±20°C, 11±1 Kb), have been studied by the Rb-Sr technique.

Three deformational events, D₁ to D₃ correlate in time with two important P,T events, here termed D₂₋₂ and D₃, D₁₋₂ reflects the continuous prograde P,T environment up to the metamorphic maximum of the two areas (D₂), while D₂ is a superimposed deformational event occuring at lower P,T conditions. According to stratigraphical constraints D₃ must have occured before or about 550 m.y. ago.

It is possible from rather complex Rb-Sr data to indicate ages for the D_1–2 and D₃ events. Two-point total rock+phengite (mica) ages together with total rock isochrons using closely spaced samples show that the main metamorphic event D_1–22 occurrred at about 800 m.y. in both areas. Similar data suggest that the superimposed event D₃ occurred between 550 and 630 m.y. ago, probably near the lower age limit. This deformation (crenulation cleavage) was responsible for the local resetting of total rock and mineral systems.

Consistent with later Palaeozoic events, the Cambrian-early Ordovician Jukesian Movement and the Devonian Tabberabberan Orogeny, which affected some Rb-Sr mineral systems (phengite, amphibole and chlorite), have ages of 500±20 m.y. and 385-350 m.y. respectively.

Due to dispersion of the eclogite total rock data points along secondary isochrons it is difficult to estimate an original age. The age of the original minerals must however have been set by the 800 m.y. D_1–2 event, as the P,T history of the eclogite is the same as that of the surrounding schists.