藏东类乌齐地区古近纪钾质火山岩的发现及特征

古近纪业阿供组火山岩分布于西藏东部类乌齐镇业阿供村,LA-ICP-MS锆石U-Pb年龄为30.54±0.8Ma,岩石具有高碱、低Ti的特征,在SiO2-K2O图解中位于钾质岩区,属于碱性钾质岩。岩石地球化学特征表明,业阿供组钾质火山岩很可能源于古俯冲流体交代的富集地幔源区经过部分熔融作用,形成于碰撞后的板内构造环境。     

Intrafolial folds and associated structures in a progressive strain environment of Darjeeling-Sikkim Himalaya

The Dating rocks and Darjeeling gneisses, which constitute the Sikkim dome in eastern Himalaya, as well as the Gondwana and Buxa rocks of ‘Rangit Window’, disclose strikingly similar sequences of deformation and metamorphism. The structures in all the rocks belong to two generations. The structures of early generation are long-limbed, tight near-isoclinal folds which are often intrafolial and rootless. These intrafolial folds are associated with co-planar tight folds with variably oriented axes and sheath folds with arcuate hinges. Penetrative axial plane cleavage and mineral lineation are related structures; transposition of bedding is remarkable. This early phase of deformation (D ₁) is accompanied by constructive metamorphism. The structures of later generation are open, asymmetrical or polyclinal; a crenulation cleavage or discrete fracture may occur. The structures of early generation are distorted by folds of later generation and recrystallized minerals are cataclastically deformed. Recrystallization is meagre or absent during the later phase of deformation (D ₂). The present discussion is on structures of early generation and strain environment during theD ₁ phase of deformation. The concentration of intrafolial folds in the vicinity of ductile shear zones and decollement or detachment surface (often described as ‘thrust’) may be considered in this context. The rocks of Darjeeling-Sikkim Himalaya display minor structures other than intrafolial folds and variably oriented co-planar folds. The state of finite strain in the rocks, as observed from features like flattened grains and pebbles, ptygmatic folds and boudinaged folds indicate combination of flattening and constrictional type strain. The significance of the intrafolial folds in the same rocks is discussed to probe the environment of strain during progressive deformation (D ₁).     

Metamorphism and tectonics of a Pan-African terrain in southeastern Sinai

The Precambrian crystalline basement of Sinai represents a low-pressure metamorphic terrain intruded by large volumes of granitic rock. Based on detailed fieldwork, a general assessment of the metamorphic and tectonic history of the Wadi Kid area, southeastern Sinai, is presented. Three lithostratigraphic units can be traced over the whole area; the Umm Zariq Formation (arkoses, greywackes, pelites), the Tarr Formation (dolomitic-calcareous rocks) and, unconformably overlying the previous two units, the Heib Formation (flows, pyroclastics, conglomerates). D₁ deformation of this 3.5 km thick sequence resulted in upright folds, with changing strike of the axial planes from NE to NW across the area. Low-grade conditions prevailed during this phase. D₂ produced recumbent folds and a subhorizontal cleavage, leading to transposition of D₁ structures in the higher grade parts of the area. Metamorphism reached its peak conditions around D₂. Pressures are estimated at 2.5–3.5 kb, whereas temperatures vary from 450–660°C. In the central Wadi Kid area, garnet, staurolite, cordierite and andalusite occur in metapelitic rocks. Highest grade rocks are syn-D₂ andalusite—K-feldspar gneiss diapirs. Metamorphic zones are shallow dippin and form a domed pattern. Most of the metavolcanics and the syntectonic and late tectonic plutonic rocks belong to the calc-alkaline suite.The Kid Group sediments and volcanics were deposited in a shallow basin and subaerially, respectively, probably on older sialic basement. This basement is at present not exposed because post-orogenic uplift directly after the Pan-African event was relatively small (3–6 km). Metamorphism and the D₂ formation phase can both be related to a rising (mafic?) diapir. The Sinai Peninsula may have been a continental margin or a cratonized, mature island arc, in Late Proterozoic times.     

http://www.sciencedirect.com/science/article/pii/S1674987113000054

Substantial part of the northern margin of Indian plate is subducted beneath the Eurasian plate during the Caenozoic Himalayan orogeny, obscuring older tectonic events in the Lesser Himalaya known to host Proterozoic sedimentary successions and granitic bodies. Tectonostratigraphic units of the Proterozoic Lesser Himalayan sequence (LHS) of Eastern Himalaya, namely the Daling Group in Sikkim and the Bomdila Group in Arunachal Pradesh, provide clues to the nature and extent of Proterozoic passive margin sedimentation, their involvement in pre-Himalayan orogeny and implications for supercontinent reconstruction. The Daling Group, consisting of flaggy quartzite, meta-greywacke and metapelite with minor mafic dyke and sill, and the overlying Buxa Formation with stromatolitic carbonate-quartzite-slate, represent shallow marine, passive margin platformal association. Similar lithostratigraphy and broad depositional framework, and available geochronological data from intrusive granites in Eastern Himalaya indicate strikewise continuity of a shallow marine Paleoproterozoic platformal sequence up to Arunachal Pradesh through Bhutan. Multiple fold sets and tectonic foliations in LHS formed during partial or complete closure of the sea/ocean along the northern margin of Paleoproterozoic India. Such deformation fabrics are absent in the upper Palaeozoic–Mesozoic Gondwana formations in the Lesser Himalaya of Darjeeling-Sikkim indicating influence of older orogeny. Kinematic analysis based on microstructure, and garnet composition suggest Paleoproterozoic deformation and metamorphism of LHS to be distinct from those associated with the foreland propagating thrust systems of the Caenozoic Himalayan collisional belt. Two possibilities are argued here: (1) the low greenschist facies domain in the LHS enveloped the amphibolite to granulite facies domains, which were later tectonically severed; (2) the older deformation and metamorphism relate to a Pacific type accretionary orogen which affected the northern margin of greater India. Better understanding of geodynamic evolution of the northern margin of India in the Paleoproterozoic has additional bearing on more refined model of reconstruction of Columbia.     

大别山东段晋宁期变质侵入岩特征及其构造演化

晋宁期变质侵入岩是大别山造山带主体组成部分，从地质、地球化学及同位素年龄等方面阐述了其基本特征，源岩属壳幔重熔型钙碱性岩浆组舍，受纬向伸展、经向挤压力控制剪切侵住。受加里东期、印支期、燕山期三期强烈改造，以大型穹状、隆滑韧性剪切带为特征．提出了非深俯冲板块构造演化基本思路。     

冈底斯西段第四纪钾质火山岩的发现及赛利普组的建立

冈底斯西段赛利普一带分布有大面积的钾质火山岩,以前曾被划归上新世一早更新世赛利普群。作者对这套火山岩地层进行了详细野外调查并重新测制了火山岩地层剖面,在该套火山岩下伏及层间湖相碎屑沉积层中获得ESR年龄0．268Ma与0．349Ma。岩石学、岩石化学研究表明,这套火山岩是以安粗质熔岩为主的钾玄岩系列一钾质碱性玄武岩系列火山岩,岩石类型及岩石组合稳定,岩层产状平缓,岩石新鲜,层位相对清楚,故将其命名为赛利普组,属第四纪早一中更新世。这一发现对研究冈底斯构造带新生代以来岩浆活动、构造演化,进而探讨青藏高原隆升机制有着重要的地质意义。     

山东汤头盆地钾质及钠质火山岩的年代学与地球化学:对华北克拉通岩石圈减薄的启示

山东汤头盆地位于沂沭断裂带南段,盆地内广泛发育以粗安质岩石为主体的晚中生代火山岩,这套岩石主要可归为碱性系列,按化学组成可进一步区分为钾质和钠质二种类型。钾质火山岩的主要岩性为黑云母粗安质火山碎屑岩和潜火山岩,钠质火山岩主要为辉石粗安质潜火山岩,其中钾质火山岩是盆地内火山岩的主体。锆石LA-ICP-MS U-Pb定年获得钾质和钠质火山岩的成岩年龄分别为124.0±1.3Ma和106.4±4.0Ma,表明钠质火山岩较钾质火山岩形成晚。在化学组成上,钾质火山岩较钠质火山岩全碱含量更高,二者的K2O+Na2O含量分别为11.02%～11.37%和8.75%～8.93%。它们均富轻稀土和大离子亲石元素,但钾质火山岩较钠质火山岩稀土总量更高,且更富轻稀土,二者的∑REE值分别为360.1×10-6～417.0×10-6和232.3×10-6～291.0×10-6,(La/Yb)N比值分别为62.02～64.66和40.32～40.52。钾质火山岩的Cs、Rb、Ba、Th、U、Pb等大离子亲石元素和Zr、Hf等高场强元素均较钠质火山岩富集,但Sr、Ti的含量偏低。钾质与钠质火山岩均具有富集的Sr-Nd同位素组成特征,但钠质火山岩的ISr值偏低、而εNd(t)值偏高,二者的ISr和εNd(t)值分别为0.7107～0.7119和-15.48～-16.96,以及0.7098和-10.03。元素和Sr-Nd同位素组成的系统分析表明浅部地壳混染对火山岩地球化学特征未产生显著影响,二类火山岩地球化学特征的变异应主要受控于岩浆源区组成的不同,而不是岩浆演化过程的差异所致。二元混合模拟指示二类火山岩均最可能起源因华北克拉通下地壳拆沉而形成的富集地幔的熔融,但钠质火山岩源区含有较高比例的亏损软流圈地幔组分。根据对火山岩地质与地球化学特征的综合分析,表明郯庐断裂持续的引张促使岩石圈减薄,并诱发深部软流圈熔体上涌,这一上涌的软流圈熔体随后又与原先富集的岩石圈地幔混合,从而导致晚期的钠质火山岩源区中含有较高的亏损软流圈地幔组分。火山岩成分由钾质向钠质演化,是软流圈地幔上涌并置换原有岩石圈地幔,最终导致华北克拉通减薄的直接响应。     

囊谦盆地新生代钾质火山岩成因岩石学研究

囊谦新生代钾质火山岩形成于碰撞后的板内构造环境,基性、中性和中酸性熔岩之间不存在分异和演化的关系,它们地球化学性质上的差异是源区部分熔融程度不同所致;钾质岩浆形成于50～80 km深处的富集交代地幔.横断山地区一些拉分盆地中火山岩源区的部分熔融可能与来自软流圈小而分散的上涌体的底侵有关.大型走滑断裂带的强烈活动为熔体的快速上升提供了通道.     

三江北段东莫扎抓矿区构造变形特征

已有关于青藏高原隆升的各种构造模型多重视新生代变形而忽略了早期构造变形的限制.本文以三江北段东莫扎抓矿区为研究对象,通过详细的构造-岩相填图,恢复了矿区二叠纪以来变形序列,结合区域资料讨论了变形事件的大地构造背景.研究表明矿区发育中-下二叠统九十道班组灰岩、上二叠统那益雄组碎屑岩、上三叠统结扎群甲丕拉组碎屑岩和上三叠统结扎群波里拉组灰岩4套地层系统,二叠系与三叠系之间为不整合接触,局部被近南北向逆断层代替.北西向逆断层横亘矿区,断层上盘三叠纪碎屑岩和灰岩整体北倾,断层下盘三叠纪岩石被左右两条走滑断层夹持向南挤出.在图面和露头尺度上矿区叠加褶皱明显,南北向剖面上多见紧闭的倾伏褶皱,近东西向剖面上则为开阔水平的斜歪褶皱,表明南北向剖面上观察到的是已被叠加的早期褶皱,为矿区第一期变形,其形成与三叠纪末古特提斯洋盆闭合有关.始新世晚期印-亚大陆碰撞地壳缩短形成矿区第二期构造,即北西向逆断层和褶皱叠加.第三期近南北向逆断层可能形成于始新世末,与印-亚大陆碰撞引起的侧向旋转有关.     

Geology,structure and age of the Nahuel Niyeu Formation in the Aguada Cecilio area,North Patagonian Massif,Argentina

The low-grade Nahuel Niyeu Formation in the Aguada Cecilio area (40°50′S–65°53′W) shows ultramafic to felsic metaigneous rocks forming a sill swarm intercalated in the metasedimentary sequence and a polyphase deformation which permit an integrated study of the magmatic and tectonometamorphic evolution of this geological unit.In this paper we present a geological characterization of the Nahuel Niyeu Formation in the Aguada Cecilio area combining mapping, structural and metamorphic analysis with a SHRIMP U–Pb age and geochemical data from the metaigneous rocks.The metasedimentary sequence consists of alternating metagreywackes and phyllites, and minor metasandstones and granule metaconglomerates. The sills are pre-kinematic intrusions and yielded one SHRIMP U–Pb, zircon crystallization age of 513.6 ± 3.3 Ma. Their injection occurred after consolidation of the sedimentary sequence. A syn-sedimentary volcanic activity is interpreted by a metaandesite lava flow interlayered in the metasedimentary sequence. Sedimentary and igneous protoliths of the Nahuel Niyeu Formation would have been formed in a continental margin basin associated with active magmatic arc during the Cambrian Epoch 2. Two main low-grade tectonometamorphic events affected the Nahuel Niyeu Formation, one during the Cambrian Epoch 2–Early Ordovician and the other probably in the late Permian at ∼260 Ma. Local late folds could belong to the final stages of the late Permian deformation or be even younger.In a regional context, the Nahuel Niyeu and El Jagüelito formations and Mina Gonzalito Complex show a comparable Cambrian–Ordovician evolution related to the Terra Australis Orogen in the south Gondwana margin. This evolution is also coeval with the late and early stages of the Pampean and Famatinian orogenies of Central Argentina, respectively. The late Permian event recorded in the Nahuel Niyeu Formation in Aguada Cecilio area is identified by comparable structures affecting the Mina Gonzalito Complex and El Jagüelito Formation and resetting ages from granitoids. This event represents the Gondwanide Orogeny within the same Terra Australis Orogen.     

ANALYSIS OF FOLDS SOUTH OF MALAKAND AND ADJOINING AREAS, NORTH PAKISTAN

ANALYSIS OF FOLDS SOUTH OF MALAKAND AND ADJOINING AREAS, NORTH PAKISTAN1　Can啨ｒｏｔＪ,QuG .CuadernosdeGeologiaiberica ,1998,2 4:311～ 331. 2　DebelmasJ,MascleG .EnsSciencesdelaTerre[M ].Masson ,ed .1991.2 99.3　GaetaniM ,GarzantiE .AAPGBull ,1991,75 (9) :142 7～ 144 6 . 4　HendrixMS ,GrahamSA ,CarrollAR ,etal.GeolSocAmBull,1992 ,10 4:5 3～ 79.. 5　Jia ,Coll.PetroleumIndustryPress,Beijing .1997,2 95 . 6　JiaD ,LuHCaiD ,etal.AAPGBull ,8…     

由伊利石结晶度研究桂西右江地区区域极低级变质作用

运用伊利石结晶度Kübler指数将桂西右江地区下三叠统罗楼群和中三叠统百逢组下段划归为浅层变质带(K.I△2θ°为0.22～0.25);将中三叠统百逢组上段和河口组划归为近变质带,中三叠统百逢组上段为高级近变质带(K.I△2θ°为0.26～0.33);中三叠统上部河口组为低级近变质带(K.I△2θ°为0.38～0.40),不排除局部为成岩带的可能.地层柱自下向上,伊利石结晶度Kübler指数由小变大,变质程度由高变低,而且,变质作用级别与岩层在地层柱中位置协调以及变质带边界与地层界线趋于一致,证明为区域埋藏极低级变质作用.凌云明山金矿区剖面矿体和百逢组各层段伊利石结晶度Kübler指数为0.42～0.50,属成岩带,且没有明显时空变化规律.     

大别山高压、超高压变质岩结构构造的演化规律(PTt-D轨迹)

根据大别山高压、超高压变质岩的中尺度-显微构造分析及PTt研究,建立它们的结构和构造随变质作用（前榴辉岩相、超高压变质峰期、前角闪岩相和角闪岩相）有序演化的PTt-D轨迹。这一演化主要包括：在岩石的矿物结构方面从石榴石静态重结晶结构到柯石英假像及放射状张裂隙构造;在岩石组构方面从L>S到L-S和S>L榴辉岩;以及在中尺度构造方面发育的D1和D2变形构造。该PTt-D轨迹同时可以提供有关高压、超高压变质岩折返模式的信息。     

Timing of metamorphism and deformation in the Swat valley,northern Pakistan:Insight into garnet-monazite HREE partitioning

New metamorphic petrology and geochronology from the Loe Sar dome in the Swat region of northern Pakistan place refined constraints on the pressure, temperature and timing of metamorphism and deformation in that part of the Himalayan orogen. Thermodynamic modelling and monazite petrochronology indicate that metamorphism in the area followed a prograde evolution from ～525 ± 25 ℃and 6 士 0.5 kbar to ～610 ± 25 ℃ and 9 士 0.5 kbar, between ca. 39 Ma and 28 Ma. Partitioning of heavy rare earth elements between garnet rims and 30-28 Ma monazite are interpreted to indicate coeval crystallization at peak conditions. Microtextural relationships indicate that garnet rim growth post-dated the development of the main foliation in the area. The regional foliation is folded about large-scale N-S trending fold axes and overprinting E-W trending folds to form km-scale domal culminations. The textural relationships observed indicate that final dome development must be younger than the 30-28 Ma monazite that grew with garnet rims post-regional foliation development, but pre-doming-related deformation. This new timing constraint helps resolve discrepancy between previous interpretations,which have alternately suggested that N-S trending regional folds must be either pre-or post-early Oligocene. Finally, when combined with existing hornblende and white mica cooling ages, these new data indicate that the study area was exhumed rapidly following peak metamorphism.     

Relative timing of deformational,metamorphic and mineralisation events at the Mt. Todd (Yimuyn Manjerr) Mine,Pine Creek Inlier,Northern Territory,Australia

The Mt. Todd Mine (also known as the Yimuyn Manjerr Mine), located approximately 40 km northwest of the township of Katherine, in the Northern Territory, Australia, is host to several discrete ore bodies that strike NNE within a broad NE-trending corridor of gold mineralisation. The mine lies in the southern region of the Central Domain of the Pine Creek Inlier (PCI) and is hosted by a Palaeoproterozoic sequence of rocks termed the Burrell Creek Formation, which is dominated by greywacke, siltstone, sandstone and shale that exhibit sedimentary features akin to those of a river-dominant delta front to prodelta environment. The formation is conformably overlain by volcanoclastic and volcanolithic sedimentary rocks of the Tollis Formation (∼1890 Ma).Three deformation events are recognised in the Mt. Todd region, D1, D2 and D3. The earliest deformation, D1, is characterised by close to tight, NE to N to NW-trending asymmetric folds (F1), and a continuous axial–planar cleavage (S1). The deformation is associated with the development of conjugate buck–quartz veins and was preceded by the emplacement of the Yenberrie Leucogranite, which produced contact metamorphism of the sedimentary rocks of the Burrell Creek Formation to hornblende–hornfels facies (H1), with the development of cordierite porphyroblasts (type C1). D1 was coincident with peak regional metamorphism to greenschist facies.D2 is associated with westerly trending open folds (F2), and a spaced disjunctive to fracture cleavage (S2) in transection to the folds. It was preceded by the emplacement of the Tennysons Leucogranite of the Cullen Batholith (1835–1820 Ma), which produced contact metamorphism of the Yenberrie Leucogranite and the sedimentary rocks of the Burrell Creek and Tollis formations to hornblende–hornfels facies (H2), with the development of cordierite porphyroblasts (type C2).D3 is characterised by the reactivation of strike-slip faults (mostly sinistral), a steeply dipping Type S3-C type foliation, and mesoscopic en échelon folds (F3) that trend oblique to the faults in a left stepping (sinistral) array.The age of emplacement of the Tennysons Leucogranite, and the timing of D1 and D2 are broadly constrained by the age of emplacement of the Cullen Batholith at 1835–1800 Ma. D1 and D2 are correlated with deformation during the Maud Creek Event (∼1850 Ma), while D3 is correlated with deformation during the Shoobridge Event (∼1780 Ma). The age of the Yenberrie Leucogranite is constrained to the age of emplacement of granite batholiths at 1870–1860 Ma.A temporal and broad structural relationship exists between D2 structures, the Tennysons Leucogranite, and the several gold-bearing quartz–sulphide veins and lode systems of the Mt. Todd Mine. The systems appear to have formed after peak thermal metamorphism associated with the emplacement of the pluton at about 1825 Ma, and early in D2, prior to the development of the regional S2 fabric. W–Mo–Sn–Bi–Cu greisen-type mineralisation in the carapace of the Yenberrie Leucogranite of the Yenberrie Wolfram Field constitutes a discrete mineralising event that preceded the emplacement of the Tennysons Leucogranite.     

滇西南云县三叠纪火山岩组合及系列的厘定及其构造意义

本文重新厘定了云县三叠纪火山岩的组合和系列,识别了4个层位中的酸性熔结凝灰岩,重新划分了火山喷发旋回和韵律。中三叠统忙怀组(T_2m)为富硅富铝高钾流纹质火山岩组合,该旋回由5个喷发韵律层组成;上三叠统小定西组(T_3x)为高钾玄武岩-钾玄岩-安粗岩及火山碎屑岩组合,该旋回由6个喷发韵律层组成。芒汇河组(T_3mh)为钾质粗面玄武岩-高钾流纹质火山岩组合,该旋回由6个喷发韵律层组成。T_2m火山岩属碰撞型弧火山岩,T_3x和T_3mh火山岩属钾玄岩系列火山岩,具有滞后型弧火山岩之属性。     

拉萨地块西段中新世查加寺钾质火山岩岩石成因*——岩石地球化学、年代学和Sr-Nd同位素约束

通常认为,青藏高原碰撞后钾质超钾质岩是交代富集上地幔低度部分熔融的产物,而最近的研究则表明,钾质火山岩也可以起源于下地壳源区.文章对青藏高原拉萨地块西段新识别出的查加寺火山岩进行了岩石地球化学、锆石SIMS U-Pb定年和Sr-Nd同位素研究,结果表明其岩石类型为碱性系列钾质粗面岩,锆石SIMS U Pb 年龄为(23.97±0.28) Ma,说明火山活动为中新世.钾质粗面岩显示出富集LREE及LILE(K、Rb、Ba、Th、U、Pb)、亏损HFSE(Ti、Nb、Ta、P),具有类似于埃达克质岩的稀土元素分布模式和微量元素蛛网图分布模式的特征;具有高的La/Yb比值(81～105)、较高的ω(Sr)(409×10-6～472×10-6)、较高的Sr/Y比值(28-37)、较低的ω(Y)(11.5×10-6～15.7×10-6)、明显亏损重稀土元素Yb(0.78×10-6～1.08×1)-6)、较高的w(Al2O3)(15.47％～16.7％)、较低的w(MgO)(0.63％～2.12％),无明显的Eu、Sr负异常,类似于典型的埃达克岩成分特征;具有高的w(K2O)(6.28％～6.97％)、高的Rb/Sr比值(0.94～1.03)和低的Ba/Rb比值(2.21～2.51),以及Na2O、K2O与SiO2无明显的相关关系,表明源区的富钾矿物是以金云母为主;具有较低的ω(Cr) 、ω(Ni)(分别为53.4×10-6～69.4×10-6,11.4×10-6～23.5×10-6),以及较低的εNd值(-12.6～-11.8)和较高的87Sr/86Sr比值(0.73207～0.73249).所有这些特征都表明,查加寺钾质粗面岩起源于拉萨地块增厚下地壳富钾物质的部分熔融.查加寺钾质粗面岩具有约145Ma、75 Ma和30 Ma等3组继承锆石年龄群.     

拉萨地块麻江地区具有“超钾质”成分的钾质火山岩的识别及成因

一般认为青藏高原拉萨地块后碰撞钾质-超钾质岩浆活动由西向东逐渐喷发,然而本文在拉萨地块中部麻江地区识别出一套钾质火山岩,利用单矿物金云母的40Ar-39Ar方法确定其形成于21.3Ma.这套火山岩具有高镁(＞3％)和高钾( K2O/Na2O ＞2)等的超钾质火山岩成分特征,但其高的MgO含量是因岩石中含有后期蚀变矿物白...     

An interpretation of the structure of the Blatherskite Nappe,Alice springs,Northern Territory

The basal unit of the Amadeus Basin sequence is the Heavitree Quartzite, and this formation usually forms a single east‐west ridge along the northern side of the MacDonnell Ranges. However, at Alice Springs there are two such ridges. Basement rocks crop out on the northern side of each ridge, and dolomite and shale of the Bitter Springs Formation crop out on their southern sides. The northern outcrop of dolomite and shale is tightly folded, and is separated from the southern outcrop of basement by a major fault. The bedding of the sediments, the axial plane of the fold, and the fault all dip south at about 45°. Inverted facings on parasitic folds indicate that the northern outcrop of quartzite and dolomite plus shale is an antiform in inverted rocks. Hence the southern outcrop of basement and quartzite is synformal, and is interpreted as the frontal part of a fold nappe. The nappe started as a recumbent anticline whose middle limb of quartzite sheared out as the anticline travelled several kilometres southwards relative to the dolomite and shale below, which formed a tight recumbent syncline. Later monoclinal uplift of the northern half of the area tilted the nappe into its present south‐dipping attitude, thus converting the recumbent anticline into a synform and the recumbent syncline into an antiform.     

鞍山附近“樱桃园组”的构造样式及其时代讨论

本文区分了“樱桃园组”岩石在元古主构造旋回的三幕变形,详细描述了各幕SFL组合和按区段进行了投影。主变形幕D₁的构造最发育,F₁控制着本区的岩性分布。构造序列及样式变化显示由高塑性向脆性的变形格式。本组与下伏的太古鞍山群变粒岩在构造序列、样式和变质相上都有显著差异,过去许多地质学家把二者混划为一个单位,统名“鞍山群”,属太古宙。但本组与上覆的辽河群(上元古)的构造样式和变质相却相似,故其时代相当于早元古Ferrian期。