Stages of development in the Polish Carpathian Foredeep basin

In southern Poland, Miocene deposits have been recognised both in the Outer Carpathians and the Carpathian Foredeep (PCF). In the Outer Carpathians, the Early Miocene deposits represent the youngest part of the flysch sequence, while in the Polish Carpathian Foredeep they are developed on the basement platform. The inner foredeep (beneath the Carpathians) is composed of Early to Middle Miocene deposits, while the outer foredeep is filled up with the Middle Miocene (Badenian and Sarmatian) strata, up to 3,000mthick. The Early Miocene strata are mainly terrestrial in origin, whereas the Badenian and Sarmatian strata are marine. The Carpathian Foredeep developed as a peripheral foreland basin related to the moving Carpathian front. The main episodes of intensive subsidence in the PCF correspond to the period of progressive emplacement of the Western Carpathians onto the foreland plate. The important driving force of tectonic subsidence was the emplacement of the nappe load related to subduction roll-back. During that time the loading effect of the thickening of the Carpathian accretionary wedge on the foreland plate increased and was followed by progressive acceleration of total subsidence. The mean rate of the Carpathian overthrusting, and north to north-east migration of the axes of depocentres reached 12 mm/yr at that time. During the Late Badenian-Sarmatian, the rate of advance of the Carpathian accretionary wedge was lower than that of pinch-out migration and, as a result, the basin widened. The Miocene convergence of the Carpathian wedge resulted in the migration of depocentres and onlap of successively younger deposits onto the foreland plate.     

The Northern Carpathians plate tectonic evolutionary stages and origin of olistoliths and olistostromes

The olistostromes formed in Northern Carpathians during the different stages of the development of flysch basins, from rift trough post-rift, orogenic to postorogenic stage. They are known from the Cretaceous, Paleocene, Eocene, Oligocene and Early Miocene flysch deposits of main tectonic units. Those units are the Skole, Subsilesian, Silesian, Dukla and Magura nappes as well as the Pieniny Klippen Belt suture zone. The oldest olistoliths in the Northern Carpathians represent the Late Jurassic-Early Cretaceous rifting and post-rifting stage of the Northern Carpathians and origin of the proto-Silesian basin. They are known from the Upper Jurassic as well as Upper Jurassic-Lower Cretaceous formations. In the southern part of the Polish Northern Carpathians as well as in the adjacent part of Slovakia, the olistoliths are known in the Cretaceous- Paleocene flysch deposits of the Pieniny Klippen Belt Zlatne Unit and in Magura Nappe marking the second stage of the plate tectonic evolution - an early stage of the development of the accretionary prism. The most spectacular olistostromes have been found in the vicinity of Haligovce village in the Pieniny Klippen Belt and in Jaworki village in the border zone between the Magura Nappe and the Pieniny Klippen Belt. Olistoliths that originated during the second stage of the plate tectonic evolution occur also in the northern part of the Polish Carpathians, in the various Upper Cretaceous-Early Miocene flysch deposits within the Magura, Fore-Magura, Dukla, Silesian and Subsilesian nappes. The Fore-Magura and Silesian ridges were destroyed totally and are only interpreted from olistoliths and exotic pebbles in the Outer Carpathian flysch. Their destruction is related to the advance of the accretionary prism. This prism has obliquely overridden the ridges leading to the origin of the Menilite-Krosno basin.

In the final, postcollisional stage of the Northern Carpathian plate tectonic development, some olistoliths were deposited within the late Early Miocene molasse. These are known mainly from the subsurface sequences reached by numerous bore-holes in the western part of the Polish Carpathians as well as from outcrops in Poland and the Czech Republic.

The largest olistoliths (kilometers in size bodies of shallow-water rocks of Late Jurassic-Early Cretaceous age) are known from the Moravia region. The largest olistoliths in Poland were found in the vicinity of Andrychów and are known as Andrychów Klippen. The olistostromes bear witness to the processes of the destruction of the Northern Carpathian ridges. The ridge basement rocks, their Mesozoic platform cover, Paleogene deposits of the slope as well as older Cretaceous flysch deposits partly folded and thrust within the prism slid northward toward the basin, forming the olistostromes.     

Tectonics of the western part of the Polish Outer Carpathians

The western part of the Polish Outer Carpathians is built up from the thrust, imbricated Upper Jurassic-Neogene flysch deposits. The following Outer Carpathian nappes have been distinguished: Magura Nappe, Fore-Magura group of nappes, Silesian, Subsilesian and Skole nappes. Interpretation of seismic and magnetotelluric survey from the region South of Wadowice, allows observation of relationship between basement and flysch nappes in the Outer Carpathians. It also allows identification of dislocation cutting both flysch nappes and their basement. All the Outer Carpathian nappes are thrust over the southern part of the North European Platform. The platform basement is composed of older Precambrian metamorphic rocks belonging to the Bruno-Vistulicum terrane. Sedimentary cover consists of Paleozoic, Mesozoic and Neogene sequences. The characteristic features of this boundary are horsts and troughs of general direction NW-SE, turning W-E. Faults cutting only the consolidated basement and the Paleozoic cover were formed during the Hercynian Orogeny in the Carboniferous and the Early Permian. Most of the older normal faults were covered by allochtonous flysch nappes forming thus the blind faults. During the last stage of the geodynamic development the Carpathians thrust sheets moved towards their present position. Displacement of the Carpathians northwards is related to development of dextral strike-slip faults of N—S direction. The orientation of this strike-slip fault zones zone more or less coincides with the surface position of the major faults perpendicular to the strike of the Outer Carpathian thrustsheets. The huge fault cuts formations from the Paleozoic basement through the flysch allochton between the boreholes in Sucha Beskidzka area. The displacement of nappes of the Carpathian overthrust and diapiric extrusion of plastic formations of the lower flysch units occurred along this fault.     

玉树地区东莫扎抓和莫海拉亨铅锌矿床Rb-Sr和Sm-Nd等时线年龄及其地质意义

青海玉树地区的东莫扎抓和莫海拉亨铅锌矿床是"三江"北段铜铅锌多金属成矿带铅锌矿床的典型代表,处于玉树逆冲推覆构造带的前锋带位置.本文利用单矿物闪锌矿和共生矿物组合黄铁矿与方铅矿Rb-Sr等时线方法以及共生矿物组合闪锌矿与黄铁矿Sm-Nd等时线方法测定东莫扎抓矿床的成矿时代为34.7～35.7 Ma,平均为35 Ma;利用单矿物闪锌矿和共生矿物组合闪锌矿与方铅矿Rb-Sr等时线方法以及单矿物萤石和共生矿物组合方解石与萤石Sin-Nd等时线方法测定莫海拉亨矿床的成矿时代为31.8～33.9 Ma,平均为33 Ma,表明2个矿床的成矿时代基本一致,为同期同源成矿作用的产物.结合区域成矿地质背景,建立了2个矿床的构造控矿模式.此外,本文获得的玉树地区典型铅锌矿床的成矿时代与"三江"南段兰坪盆地和"三江"北段沱沱河盆地铅锌矿床的成矿时代相近,证明青藏高原东部和北部受逆冲推覆控制的长达1 000 km的狭长地带有望成为一条巨型Pb-Zn成矿带.     

准噶尔盆地南缘古近纪—新近纪前陆盆地沉积格局与演变*

针对准噶尔盆地南缘古近系和新近系碎屑岩沉积体,运用野外露头宏观分析与岩心、薄片微观描述来 “定岩相和沉积相”;依据地震相的不同特点及相变的不同位置,刻画湖岸线演化,从而对沉积体“定边界”;根据重矿物组合特征及砂岩等厚图来“定主次物源”的方法,综合研究前陆盆地的沉积相特征。在此基础上,分析了准噶尔盆地南缘湖盆沉积格局与演变,认为准噶尔盆地南缘古近系紫泥泉子组沉积时期,湖平面较低,天山山前带发育4个规模较大的扇三角洲朵状体;至安集海河组沉积时期,湖平面上升,山前带扇三角洲发生退积,仅沉积3个规模变小的朵状体,霍尔果斯地区扇三角洲朵状体不发育。新近系沙湾组沉积时期,由于逆冲推覆构造作用,山前带地形高差大、坡度陡且气候干旱,随着湖平面的迅速下降,山前带发育更大规模进积型扇三角洲沉积。准噶尔盆地南缘古近系—新近系2个主要物源分别是中部东湾—吐谷鲁—玛纳斯背斜、西部西湖—独山子背斜;2个次要物源分别为东部呼图壁背斜和中西部霍尔果斯背斜,此4个物源流向是由南向北。北部卡因迪克地区则是来自前陆隆起区的重要物源。     

Earthquake-induced resedimentation in the Badenian (middle Miocene) gypsum of southern Poland

In the Badenian (middle Miocene) basin of the Carpathian foreland of southern Poland, gypsum breccias occur associated with laminated gypsum deposits. These breccias consist of large clasts of gypsum, carbonates, marls and clay chips of variable size embedded in a gypsarenitic matrix. Constituent gypsum grains and clasts commonly appear to be mechanically abraded and chemically corroded crystals or fragments of selenitic, laminated and alabastrine gypsum. Gypsorudites are commonly accompanied by laminated gypsarenites and gypsolutites which show graded bedding; a vertical sequence of graded gypsum beds showing Bouma sequences may be recognized in borehole sections. Microfolding is common within the folded laminated gypsum, and is closely associated with expressions of extensional strain. Both are accompanied by pervasive microfaulting, suggesting a semi-coherent downslope mass movement. The stratiform geometry of the breccias, together with the intensity of slumping relatively independent of the palaeoslope, suggest earthquake shocks as the initial, main cause. Gypsum deposits form a constant, laterally extensive sequence of different lithofacies. The occurrence of the same lithologies and shallowing-up cycles over a wide area reflects thrusting of the Carpathians over the Carpathian foredeep. Local tectonism has also played a significant role. The tectonic framework favoured activation of dip-slip faults promoting shallow-focus earthquakes. These in turn resulted in the resedimentation of gypsum by slumps, debris flows and turbidites. A similar basinward resedimentation of clastic material by gravity flows initiated by fault-induced earthquakes could be of great importance in the foreland geological setting, and may explain some phenomena observed in other evaporite formations from different geological settings, especially of rift type.     

ON THE AGE OF METAMORPHISM IN THE JAPANESE ISLANDS

The Sivas Basin extends over a major crustal structure underlying the contact zone between the Tauride and Pontide belts. The Kirsehir block, a continental crustal element lying between the main belts, introduces a subordinate suture in front of the Pontides—the Inner Tauride suture. The junction of the two main sutures occurs between Hafikand Imranli. Four structural zones have been considered. The northern basement of the basin, which includes both the Kirsehir continental crust and thrust sheets of ophiolite and pelagic sediments, forms an imbricate stack with an Eocene cover. The Eocene cover shows two distinct sequences: marine neritic and continental basalts overlying the Kirsehir basement, and deltaic and basinal deposits lying to the southeast. Southward tectonic stacking of the entire pile has occurred repeatedly since Oligocene time. The Sivas Basin proper is separated from the Kirsehir basement by the Kizilirmak Basin. This new structural unit consists of nearly undeformed, middle Miocene sandstones and conglomerates and a Pliocene lacustrine limestone.

The Sivas Basin proper corresponds to a fold-and-thrust belt involving an Oligocene deltaic plain with intervening large-scale evaporitic stages and subsequent lower Miocene shallow-marine deposits. Three distinct tectonic domains are considered—(1) an eastern A domain, characterized by a hinterland of deep imbricate and rare northward thrusts; (2) a transitional B domain, corresponding to a series of lateral thrust branches propagating to the southwest; this domain later was deformed by the (3) C domain, displaying a foreland-dip type of stacking. The Caldag-Tecer-Gurlevik ridge forms a structural entity of topographic highs along the southern margin of the Sivas fold-and-thrust belt. Three Eocene-cored anticlinoria arranged along an E-W relay zone fold a passive-roof composite allochthon including ophiolitic elements together with Upper Cretaceous to Eocene limestone and conglomerate. The sole of this allochthon consists of Oligocene gypsum. The Kangal Basin, a large syncline cored by Pliocene continental deposits, corresponds to the southernmost unit. The boundary with the Caldag-Tercer-Gurlevik ridge is partially concealed by a lower Miocene continental basin, overlain by a N-vergent thrust of a lower Mesozoic limestone of the Taurus platform. If the southeastward propagation of thrusting in the Sivas thrust belt and related northward thrusts at a variety of scales is considered to represent the main thrust over the undeformed Kizilirmak basin, a comparison with modern analog structural features and analog models yields a coherent interpretation of this basin in terms of its forearc-prism evolution. At a larger scale, the Sivas Basin should be considered as a piggyback basin developed along the northward-rotated rear of the Tauride wedge and the synchronous southward thrusting of the Kirsehir-Pontide wedge. At least in early Miocene time, the Inner Tauride and Erzincan sutures corresponded to a single intracontinental thrust zone along which part of the displacement of the southern front of the Tauride has been progressively transferred.     

Foraminiferal record of marine transgression during deposition of the Middle Miocene Badenian evaporites in Central Paratethys (Borków section,Polish Carpathian Foredeep)

Benthic and planktonic foraminifera from a marly clay intercalation sandwiched between mid‐Badenian (Middle Miocene) gypsum deposited in an environment of an evaporitic shoal (<1 m deep) at Borków (southern Poland) indicate a major marine flooding event in the previously isolated Carpathian Foredeep Basin (Central Paratethys). After this very short‐term environmental change, benthic foraminifers started to colonize a new niche which was previously defaunated, and the pattern of benthic foraminiferal colonization is similar to that related to the reflooding which terminated the Badenian evaporite deposition. The benthic foraminifer assemblages are composed of pioneer, opportunistic, r‐selected species dominated by elphidiids. The connection of the Carpathian Foredeep Basin with the marine reservoir was short‐lived. The marly clay intercalations in evaporite sequences originating in bared basins can thus register major environmental changes.     

青藏高原羌塘盆地南部古近纪逆冲推覆构造系统

西藏羌塘地块南部古近纪发育肖茶卡-双湖逆冲推覆构造、多玛-其香错逆冲推覆构造、赛布错-扎加藏布逆冲推覆构造,构成古近纪大型逆冲推覆构造系统。沿逆冲推覆构造的前锋断层,二叠系白云岩与大理岩化灰岩、三叠系砂岩与页岩、侏罗系碎屑岩与碳酸盐岩和三叠纪—侏罗纪蛇绿岩自北向南逆冲推覆于古近纪红色砂砾岩之上,形成规模不等的构造岩片与飞来峰。羌塘盆地南部主要的逆冲断层和下伏的褶皱红层被中新世湖相沉积地层角度不整合覆盖,表明逆冲推覆构造运动自中新世以来基本停止活动。羌塘盆地南部古近纪逆冲推覆构造运动在近南北方向产生的最小位移为90km,指示新生代早期上地壳缩短率约为47%。古近纪逆冲推覆构造对羌塘盆地油气资源具有重要影响。     

Thrust front segmentation induced by differential slab retreat in the Apennines (Italy)

New seismic reflection data reveal that the south‐eastward prolongation of the Apennine thrust front in the central Adriatic Sea is most likely located in a more external position with respect to the traditional interpretation. In this new interpretation, the Apennine thrust front shows a segmented geometry in correspondence to the Tremiti lithospheric transfer zone. The available data suggest that the north‐eastward flexural retreat of the subducting Adriatic lithosphere and the related frontal accretion of the Apennine accretionary prism have acted during the last 5 Ma and may be considered still lively in both the Po plain and in the Central Adriatic domain, north of the Tremiti lineament. By analysing the tectonic evolution of the Apulo‐Adriatic areas, it may be argued that the differential slab retreat between the central and southern sectors of the subducting Adriatic plate has been able to induce the segmentation of the Apennine thrust front.     

Low-T thermochronometric evidence for post-thrusting (< 11 Ma) exhumation in the Western Outer Carpathians,Poland

Thermal indicators record exhumation of sedimentary units from depths in excess of 6 km over most of the Outer Carpathian fold and thrust belt in Poland. Apatite fission track data, showing cooling ages ranging between 32.1 ± 4.8 and 7.0 ± 0.8 Ma, indicate that exhumation was partially coeval with shortening. However, new thermochronometric information obtained as part of this study allowed us to unravel a previously undetected, post-thrusting exhumation stage. The integration of new field data and structural analysis with low-T thermochronometry suggests that termination of thrusting – at ca. 11 Ma in the area of the present study – was followed by gravity disequilibria within the orogenic wedge. The related extension and denudation phenomena appear to have played a primary role in the recent (< 10 Ma) tectonic evolution of the Western Outer Carpathians, exerting a major control on exhumation processes in this key area of the Alpine–Carpathian mountain system.     

米仓山、南大巴山前缘构造特征及其形成机制

在对四川盆地东北部盆山结合部地表地质和石油地球物理资料综合分析的基础上,阐述了米仓山前缘构造、南大巴山前缘构造的几何学、运动学特征;发现了二者的共性和不同,二者均以双重构造为主,通过古生代构造层的叠置,而迅速抬升出露地表,米仓山前缘以被动顶板双重构造为主,即典型的"三角带"构造,南大巴山前缘以主动顶板双重构造为其显著特征;初步分析了原因,区域滑脱层,特别是嘉陵江组-雷口坡组膏盐岩滑脱层及古生界泥页岩滑脱层,构成了顶板和底板逆冲断层,其间的台地相碳酸盐岩构成了断夹块,受米仓山早期基底隆升和侧向挤压,形成了被动顶板双重构造,南大巴山递进挤压变形,形成了主动顶板双重构造。     

New geophysical and geological evidence for the present day southernmost active deformational front of the Rif thrust-and-fold belt and the oceanic accretionary prism of Cadiz: the Dhar Doum–Lalla Zahra fault, Northwestern Atlantic Coastal Morocco

Combining the results from field observations, high resolution 2D-electric resistivity and high resolution seismic refraction tomography, we have found new evidence for active faulting in the Dhar Doum area, northwestern Atlantic coast of Morocco. Qualitative interpretation of the inverted resistivity and seismic refraction data reveals the presence of two thrust faults that cut the topographic surface and displace the most recent sedimentary deposits. Furthermore, one of these seismically imaged faults strongly correlates with the Dhar Doum?CLalla Zahra fault. The steepening at the surface and the flattening with depth of this fault are likely to indicate an important strike-slip component associated with a major reverse component. If extended offshore to the west, the Dhar Doum fault could be a continuation of the southernmost deformational front of the Cadiz oceanic accretionary prism. Therefore, this structure is very likely to represent the actual active southern deformational front of the oceanic accretionary prism, as well as that of the Rif fold-and-thrust belt. The southward thickening of the growth strata composing the uppermost dune system and the occurrence of Plio-Quaternary conglomerates north of the Dhar Doum?CLalla Zahra fault suggest that the neotectonic activity may have started by the end of the Pliocene and have continued to the present as indicated by the folding-and-faulting of the most recent sedimentary deposits and the presence of high scarps. The identification of active faulting in the study area that may have a profound influence on seismic hazard analysis of the whole Rif foredeep basin.     

Late neogene-quaternary tectonics of the polish Carpathians in the light of neotectonic mapping

A new neotectonic map of the Polish Carpathians, constructed on the basis of morphometric, geological, geophysical and geomorphological data, is presented. A number of morphostructures, dependent upon faults, deep crustal fractures, the thickness of flysch deposits and geophysical properties of the Carpathian substratum, have been distinguished.Neotectonic movements are regarded as being Badenian-Sarmatian and Plio-Quaternary in age, their amplitudes ranging from 2000 to 500 m. The observed neotectonic differentiation of structural elements is the combined effect of the mobility of the Carpathian substratum and of horizontal movements of the flysch nappes.     

The Caledonian thrust front and palinspastic restorations in the southern Norwegian Caledonides

The Osen-Røa thrust sheet of the southern Norwegian Caledonides comprises the coarse clastic late Precambrian Sparagmite region, and the folded and imbricated Cambro-Silurian rocks of the Oslo region. Ramp-flat geometries occur in the hangingwall of the Osen-Røa thrust in the Mjøsa district. Two major ramps are recognized. One coincides with the strike of the Ringsaker inversion, while the other coincides with the traditional thrust front in the Gjøvik area. The Osen-Røa thrust cuts up section in the transport direction (south), eventually cutting out all late Precambrian rocks, to lie as a 150 km long flat in the Cambrian Alum shales of the Oslo region. The now eroded detachment termination probably died out horizontally in the Alum shales to end as a buried thrust front in the southern Oslo region. Restoration of hanging- and footwall cutoffs allows the amount of overthrusting to be calculated; the Sparagmite region/Oslo region boundary restores to a minimum of 130 km to the NNW. This displacement estimate agrees with estimates of 135 km NNW transport calculated from balanced cross-section restorations through the Oslo region.     

Gangdese retroarc thrust belt and foreland basin deposits in the Damxung area,southern Tibet

Geologic mapping and U–Pb detrital zircon geochronologic studies of (meta)sedimentary rocks in the Damxung area (∼90 km north of Lhasa) of the southern Lhasa terrane in Tibet provide new insights into the history of deformation and clastic sedimentation prior to late Cenozoic extension. Cretaceous nonmarine clastic rocks ∼10 km southeast of Damxung are exposed as structural windows in the footwall of a thrust fault (the Damxung thrust) that carries Paleozoic strata in the hanging wall. To the north of Damxung in the southern part of the northern Nyainqentanglha Range (NNQTL), metaclastic rocks of previously inferred Paleozoic age are shown to range in depositional age from Late Cretaceous to Eocene. The metaclastic rocks regionally dip southward and are interpreted to have been structurally buried in the footwall of the Damxung thrust prior to being tectonized during late Cenozoic transtension. Along the northern flank of the NNQTL, Lower Eocene syncontractional redbeds were deposited in a triangle zone structural setting. All detrital zircon samples of Cretaceous–Eocene strata in the Damxung area include Early Cretaceous grains that were likely sourced from the Gangdese arc to the south. We suggest that the that newly recognized Late Cretaceous to Early Eocene (meta)clastic deposits and thrust faults represent the frontal and youngest part of a northward directed and propagating Gangdese retroarc thrust belt and foreland basin system that led to significant crustal thickening and elevation gain in southern Tibet prior to India-Asian collision.     

Influence of syntectonic sedimentation on thrust geometry. Field examples from the Iberian Chain (Spain) and analogue modelling

Steep thrusts are usually interpreted as oblique-slip thrusts or inverted normal faults. However, recent analogical and numerical models have emphasised the influence of surface mass-transfer phenomena on the structural evolution of compressive systems. This research points to sedimentation and erosion during deformation as an additional explanation for the origin of steeply dipping thrusts. The present study uses both field observations and analogue modelling to attempt to isolate critical parameters of syntectonic sedimentation that might control the geometry of the upper part of thrust systems.A field study of thrust systems bounding two compressive intermountain Tertiary basins of the Iberian Chain is first briefly presented. We describe the surface geometry of thrusts surrounding the Montalbán Basin and the Alto Tajo Syncline at the vicinity of deposits of Oligocene–Early Miocene alluvial fans at the footwall of faults. Field observations suggest that synthrusting sedimentation should influence the structure of thrusts. Indeed, the faults are steeper and splitted at the edge of the syntectonic deposits.Effects of sedimentation rate on footwall of thrusts, and of its change along fault strike are further investigated on two-layer brittle-ductile analogue models submitted to compression and syntectonic sediment supply. Two series of experiments were made corresponding to two end-members of depositional geometries. In the first series, the sedimentation was homogeneously distributed on both sides of the relief developed above the thrust front. In the second series, deposits were localised on a particular area of the footwall of thrust front. In all experiments, the sedimentation rate controls the number and the dip of faults. For low sedimentation rates, a single low-angle thrust develops; whereas for high sedimentation rates, a series of steeper dipping thrust is observed. In experiments with changing sedimentation rate along fault strike, the thrust geometry varies behind the areas with the thickest sediment pile.     

The vorticity axis flip and its control on mineralization

This paper discusses the possible role of vorticity axis flip in controlling fluid flow and consequent development of hydrothermal deposits. Structural, kinematic and vorticity data from the vicinity of the Singhbhum Shear Zone (SSZ) are used to propose a two stage model to explain hydrothermal mineralization. It is suggested that in the initial stage, fractures, weak planes, foliations and/or shear zones develop. Fracture permeability is weak at this stage, as a consequence of which fluid pressure builds up. Variation in stress orientation during a later stage of deformation results in enhancement of fracture network, fracture permeability and its anisotropy. If a significant vorticity axis flip accompanies this variation in stress orientation, then it pumps the fluids into the fracture network, thus yielding hydrothermal mineral deposits. In the case of SSZ, the vorticity axis flip is envisaged to have taken place from steeply plunging (anticlockwise) during the early stage, to sub-horizontal during the late stage. The SSZ became a northerly dipping thrust at this late stage and the rotation around the sub-horizontal vorticity axis was such that the rocks comprising the northern block were thrust over southern block (Singhbhum granitoid). According to the author, this vorticity axis flip must have been critical in pumping up the fluids along the SSZ to form quartz veins that host mineral deposits.     

青藏高原东北缘循化盆地渐新世—上新世沉积相分析与沉积演化

位于循化盆地南缘的积石镇羊圈贡拜—西沟上庄剖面发育连续完整的晚渐新世—上新世地层, 从老至新依次出露渐新统—中新统他拉组、中新统咸水河组(中庄段、上庄段、东乡段)和中新统—上新统临夏组(柳树段和何王家段).沉积相分析认为, 他拉组以冲积扇相为主, 咸水河组以富含膏盐层的咸化湖相—三角洲前缘相为主, 临夏组以湖相—三角洲前缘相夹水下扇相为主.通过对沉积序列中古流向的系统测量和分析, 揭示他拉组、咸水河组沉积期的古水流方向多在SE-NW之间, 结合物源分析, 表明当时西秦岭北缘逆冲带和拉脊山逆冲带均已隆起并遭受剥蚀成为循化盆地沉积物的物源供应区; 而在临夏组沉积期, 古水流以NWW为主, 推测循化盆地东部的积石山隆起成为物源的主要供应区.剖面粒度概率累积曲线和C-M图分析结果印证了对剖面沉积相的划分, 并指示盆地沉积时期的三角洲前缘和水下扇发育区存在牵引流.