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1.
The configuration of the lineament-disjunctive network in the Russian segment of the Sea of Japan (sheets K-52 and K-53) was studied with structural zoning of the region using geophysical and geomorphologic data. The constructed rose diagrams revealed systematic orientation of lineaments and faults in the region as a whole and some of its areas. The orientation of linear structures in the Russian segment of the Sea of Japan is compared with that characteristic of the global disjunctive network. This allowed the following inferences: (1) the region is characterized by a single lineament-disjunctive system with four main directions of dislocations: submeridional (0–5°), sublatitudinal (86–90°), diagonal northeastern (36–65°), and diagonal southeastern (136–140°); (2) the directions of these dislocations coincide with the orientation of four main systems in the global disjunctive network (planetary fracturing); (3) the revealed disjunctive network is substantially of the Earth’s rotation genesis; (4) regularities in the distribution and orientation of faults and lineaments are determined by two interacting factors: the stress concentration in areas of the layer thickness gradient and variations in the Earth’s rotation velocity (the former controls localization of faults and the latter, their orientation). 相似文献
2.
特提斯域是全球最重要的密西西比河谷型(MVT)铅锌矿床富集区,矿床广泛地分布在陆-陆碰撞造山带两侧的陆块上,就位于碰撞形成的褶皱-逆冲带和前陆带内,成矿通常发生在碰撞挤压作用晚期或之后、区域处于走滑或伸展的阶段。矿床、矿体的就位与张性断裂密切相关,主要控矿因素有蒸发盐底辟构造、碳酸盐岩溶蚀垮塌构造、蒸发盐溶蚀垮塌构造、高孔隙度白云岩、含重晶石地层等。油气流体在许多矿床和矿集区出现,其主要通过与硫酸盐发生反应为铅锌成矿提供还原硫。陆-陆碰撞的大地构造环境、大量的蒸发盐、丰富的油气流体是特提斯域富集MVT矿床的重要原因,域内寻找MVT矿床的潜力巨大。 相似文献
3.
探究青藏高原东南缘构造旋转变形有助于理解青藏高原内部物质向东南方向的挤出过程。目前,有关青藏高原东南缘的构造旋转研究主要针对于两套地层:侏罗系—始新统和中新统—第四系。对侏罗系—始新统研究表明了大范围的顺时针旋转变形的存在,而对中新统—第四系的研究则表明该区域可能同时存在逆时针旋转变形。然而,对这两种构造旋转变形的时间和幅度仍缺乏充分的制约。位于川滇地块的四川盐源盆地同时出露这两套地层。磁性地层研究表明,上新统—中更新统的时代为3.6~0.6 Ma。磁偏角数据揭示上新统—中更新统经历了逆时针旋转变形(-14.4°±2.7°),而古新统—始新统经历了明显的顺时针旋转(10°~21.5°),两套地层间的旋转幅度高达36.6°。鉴于青藏高原东南缘发生大规模顺时针旋转变形的最年轻地层为始新统地层,因此顺时针旋转变形可能发生在始新世—中新世某个时间段。这个时间与红河—哀牢山走滑断裂带的活动时间基本一致,因此顺时针旋转变形可能与该大型断裂带的活动直接相关。盐源盆地记录到的逆时针旋转变形发生于至少3.6 Ma以来,平均旋转速率为4°/Ma。由于磁组构数据表明上新世—中更新世地层并未受到挤压变形作用,因此其逆时针旋转变形可能受周围走滑断裂带的控制。 相似文献
4.
三江北段东莫扎抓矿区构造变形特征 总被引:3,自引:0,他引:3
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. 相似文献
5.
V. P. Utkin 《Russian Journal of Pacific Geology》2013,7(3):167-188
The spatial-genetic relationships between transit fault systems of the East Asian global shear zone (EAGSZ) are analyzed. It is established that the EAGSZ internal structure between the Okhotsk and South China seas is identical to that of world-known natural and experimental shear zones, which confirms its development as an integral structure. The structural-kinematic analysis included the Tan-Lu-Sikhote-Alin (TS) system of left-lateral strike-slip faults (NNE 25°–30°) and the Bohai-Amur (BA) system of updip-strike-slip faults (NE 50°–70°). It is shown that these systems were formed as structural parageneses during two stages. The first and shear-thrust stage (Jurassic-Early Cretaceous) was marked by general NNW-oriented compression with the formation of the TS system of left-lateral strike-slip faults and their structural parageneses (compression structures) such as the BA system of updip-thrusts. The second, strike-slip-pull apart stage (Late Cretaceous-Cenozoic) was characterized by SE-directed tangential compression, which was generated by the SW left-lateral displacement of the continental crust along the Central Sikhote-Alin deep-seated fault. In such dynamic settings, the updip-thrust kinematics of the BA system gave way to that of left-lateral strike-slip faults. The strike-slip faults were formed in the transtension regime (shear with extension), which determined the development of pull-apart structures, where the left-lateral shear extension component played the decisive role. Simultaneously, the extension involved the Tan-Lu strike-slip fault with the formation of the rift valley and the discrete development of sedimentary basins along the latter. 相似文献
6.
The Tan-Lu fault zone (TLFZ) traverses the Liaohe western depression (LHWD), affords an exceptional opportunity to reveal the structural deformation and evolution of a major strike-slip fault of the LHWD using three dimensional seismic data and well data. In this paper, based on structural interpretations of the 3-D seismic data of the LHWD, combined with depth slice and seismic coherency, a variety of structural features in relation to right-lateral strike-slip fault (the western branch of the Tan-Lu fault) have been revealed presence in the depression, such as thrust faults (Xinlongtai, Taian-Dawa, and Chenjia faults), structural wedges, positive flower structures, and en echelon normal faults. Fault cutoffs, growth strata and the Neogene unconformity developed in the LHWD verify that the activity of right-lateral strike-slip from the late Eocene to Neogene (ca. 43–23 Ma). The study indicates that the right-lateral strike-slip played an important role in controlling the structural deformation and evolution of the LHWD in the early Cenozoic. Moreover, the front structural wedge generated the gross morphology of the Xinlongtai anticline and developed the Lengdong faulted anticline during the late Eocene, and the back structural wedge refolded the Lengdong faulted anticline zone in the late Eocene to the early Oligocene. Wrench-related structures (the Chenjia thrust fault and the en echelon normal faults) were developed during the late Oligocene. Uniform subsidence in the Neogene to Quaternary. Furthermore, the driving force of the right-lateral strike-slip deformation was originated from N–S extension stress related to the opening of the Japan Sea and NE–SW compression, as the far-field effect of India–Eurasia convergence. 相似文献
7.
青海鄂拉山断裂带晚第四纪构造活动及其所反映的青藏高原东北缘的变形机制 总被引:11,自引:0,他引:11
鄂拉山断裂带是分隔青海乌兰盆地 (柴达木盆地的一部分 )与茶卡—共和盆地的一条重要边界断裂 ,长约 2 0 7km ,由 6条规模较大的主要以右阶或左阶次级断裂段羽列而成 ,阶距约 1~ 3.5km。该断裂右旋走滑的起始时代为第四纪初期 ,约在 1.8~ 3.8MaB .P .期间 ,大的地质体累积断错约 9~12km。断裂新活动形成了一系列山脊、冲沟和阶地等的右旋断错及断层崖、断层陡坎等。晚更新世晚期以来 ,鄂拉山断裂带的平均水平滑动速率为 (4 .1± 0 .9)mm/a ,垂直滑动速率为 (0 .15± 0 .1)mm/a。鄂拉山地区的构造变形受区域NE向构造应力作用下的剪切压扁与鄂拉山断裂的右旋剪切和挤压的共同影响 ,共和—茶卡盆地和乌兰盆地均属于走滑挤压型盆地。青藏高原东北缘地区在区域性北东向挤压的作用之下 ,应变被分解为沿北西西向断裂的左旋走滑和沿北北西向断裂的右旋走滑运动 ,形成一对共轭的剪切断裂。鄂拉山断裂及其他北北西走向断裂的发展演化和变形机制表明青藏高原东北缘向东的挤出和逃逸是非常有限的。 相似文献
8.
内蒙古东南部西拉木伦断裂两侧二叠纪地层中发育有一系列叠加褶皱,它们与侏罗纪地层内部褶皱及断裂变形记录了该区晚古生代以来的多期构造事件。研究这些变形对探索华北北部及邻区所经历的从古亚洲构造域到古太平洋构造域转换的动力学过程具有重要意义。二叠纪、侏罗纪地层变形的详细地质填图及叠加褶皱构造样式与区域演化序列的研究,揭示出:二叠纪地层褶皱形迹具S型展布特征,总体走向NEE,轴面倾向NW;中生代地层褶皱走向NE,轴面倾向SE,伴生逆冲断层多向SE倾斜并且上盘向NW逆冲。研究厘定区内经历三期构造变形:(D1)二叠纪末-中三叠世NNW-SSE向区域性挤压,二叠纪地层形成NEE向褶皱;(D2)晚三叠世区域性剪切作用将先期形成的NEE向褶皱改造成平面弧形褶皱,表现为Simón(2004)划分的Type2a与Type1d型叠加褶皱样式;(D3)晚侏罗世NW-SE向挤压导致中侏罗世地层中倒向NW的褶皱构造,并使得二叠纪地层褶皱更加紧闭。研究认为这三期变形可能分别代表:(1)古亚洲洋闭合和伴生的碰撞造山作用;(2)介于西拉木伦右行走滑断裂与蒙古东南部东戈壁左行走滑断裂之间块体的NEE向挤出构造;(3)古太平洋板块向欧亚大陆之下的俯冲作用。 相似文献
9.
《Journal of African Earth Sciences》2008,50(4-5):211-221
The Late Panafrican evolution of the Hoggar shield is characterized by emplacement of magmatic intrusions and by occurrence of major shear zones separating different terranes. In Telloukh granite is close to the In Guezzam faults (western border of the Tin Serririne basin). Analysis of its visible and magnetic fabrics suggests an emplacement mode and deformation that are not related to the In Guezzam faults, but most likely to a N–S compression, an event not yet identified. Dioritic dykes crosscutting the granite have a very different magnetic fabric, which is related on the contrary to dextral strike-slip movements along the In Guezzam faults. In both cases, no visible fabric can be correlated with the magnetic fabric, which has been likely acquired during late magmatic stages. This magnetic fabric was not significantly affected by the tectonic events that took place after entire crystallization of the magma. The In Guezzam faults and the major 7°30 and 4°50 shear zones are close to intrusions such as In Telloukh dykes and the Alous En Tides and Tesnou plutons where quite similar magnetic fabrics are observed, all related with dextral strike-slip movements along these structures. 相似文献
10.
Seismic‐scale continuous exposures of an Upper Carboniferous (Bashkirian–Moscovian) carbonate platform (N Spain) provide detailed information about the lithofacies and stratal geometries (quantified with differential global positioning system measurements) of microbial boundstone‐dominated, steep prograding and aggrading platform margins. Progradational and aggradational platform‐to‐slope transects are characterized by distinct lithological features and stratal patterns that can be applied to the understanding of geometrically comparable, high‐relief depositional systems. The Bashkirian is characterized by rapid progradation at rates of 415–970 m My?1. Characteristic outer‐platform facies are high‐energy grainstones with coated intraclasts, ooids and pisoids, moderate‐energy algal‐skeletal grainstones to packstones and lower energy algal packstone and boundstone units. The Moscovian aggradational phase is characterized by aggradation rates of 108 m My?1. Coated‐grain shoals are less common, whereas crinoidal bars nucleated in well‐circulated settings below wave‐base. Boundstones form a belt (30–300 m wide) at the platform break and interfinger inwards with massive algal‐skeletal wackestones (mud‐rich banks). The progradational phase has divergent outer‐platform strata with basinward dips of 12° to 2°. Steep clinoforms with dips of 20–28° are 650–750 m in relief and possibly sigmoidal to concave in the lower part. The basinward‐dipping outer‐platform strata might be depositional for less than 6°, consistent with lithofacies deepening seaward. The basinward dip is attributed to the downward shift of upper‐slope boundstone, forced by late highstand and relative sea‐level fall, and to compaction‐induced differential subsidence during progradation. The aggradational phase is characterized by horizontally layered platform strata. Clinoforms steepen to 30–45° reaching heights of 850 m and are planar to concave. The evolution from progradation to aggradation, at the Bashkirian–Moscovian boundary, is attributed to increased foreland‐basin subsidence and decreased boundstone accumulation rates. Progradation was primarily controlled by boundstone growth rather than by highstand shedding from the platform top. Within the major phases, aggradational–progradational increments are produced by third‐ to fourth‐order relative sea‐level fluctuations. 相似文献
11.
西昆仑造山带北西向拉伸线理特征及其地质意义 总被引:1,自引:0,他引:1
初步研究了西昆仑造山带广泛发育的一组NW—NWW向拉伸线理的矿物组成、产状、分布层位等特征,探讨了其成因。认为该组线理为区内第三主变形期的“陆内榨挤”阶段导致西昆仑造山带逆冲推覆断层系被激发转变为大规模NW—NWW向右旋平移走滑的产物。 相似文献
12.
《Journal of Structural Geology》2001,23(2-3):379-392
Fault-slip data are used to reconstruct varying tectonic regimes associated with transverse fold development along the eastern and southern margins of the Jaca basin, southern Pyrenees, Spain. The Spanish Pyrenean foreland consists of thrust sheets and leading-edge décollement folds which developed within piggyback basins. Guara Formation limestones on the margins of the Jaca basin were deposited synchronously with deformation and are exposed in the External Sierra. Within the transverse folds, principal shortening axes determined from P and T dihedra plots of fault-slip data show a shift from steep shortening in stratigraphically older beds to NNE–SSW horizontal shortening in younger beds. Older strata are characterized by extensional faults interpreted to result from halotectonic (salt tectonics) deformation, whereas younger strata are characterized by contraction and strike-slip faults interpreted to result from thrust sheet emplacement. The interpretation of the timing for the shortening axes in the younger strata is supported by the observation that these axes are parallel to shortening axes determined from finite strain analysis, calcite twins, and regional thrusting directions determined from fault-related folds and slickenlines. This study shows that fault population analysis in syntectonic strata provides an opportunity to constrain kinematic evolution during orogeny. 相似文献
13.
This paper deals with the regional and structural framework of the Cretaceous rocks in the Afikpo Basin located in the southeastern
part of the Lower Benue Trough. Results from regional tectonics are presented together with those of the microtectonic analysis
of microfaults in the Owutu-Afikpo-Adadama area in the basin.
The Owutu-Afikpo-Adadama ridge at the north-central part of the basin marks the boundary between the Late Cenomanian-Turonian-Conianian
sediments and the Campanian-Maastrichtian sandstones. This ridge trends N45°E on average and is faulted in three main directions,
namely: (1) N-S normal faults; (2) NE-SW strike-slip faults; and (3) NW-SE strike-slip faults. The faulted rocks along these
brittle discontinuities are mainly cataclastics with internal fracture cleavage and sigmoidal quartz mosaics that are reminiscent
of extensional deformation. The cataclasites often bear slickenside striations. 相似文献
14.
In southern Taiwan the initial collision of the Luzon volcanic arc with the passive continental margin of China results in the emergence of an accretionary prism of, predominantly, turbidites in composition, thus providing an appropriate place to study the temporal and spatial variation of deformation during the transition of subduction to arc-continent collision. Field surveys have recently been carried out in slightly metamorphosed rocks along the well-exposed Jinlun-Taimali coast in southeastern Taiwan. Three folding phases are identified in the area. The first phase is characterized by gently dipping but widely distributed phyllitic cleavage (S1). The second phase is represented by sparsely distributed crenulation cleavage (S2) that folded the phyllitic cleavage. The third phase is characterized by E–W trending antiforms (F3) that involved both types of pre-existing cleavages. Restoration of such an antiform in the north using a method proposed in this paper reveals that phyllitic cleavage in the overturned beds dips gently towards the southeast or east-southeast before the antiform, in relation to the first-phase thrusting or folding under regional ESE-WNW compression. From the first to third phase, the maximum horizontal compression underwent an about 90° anticlockwise rotation from ESE-WNW to E–W or NE–SW to N–S, and the deformation depth seems to decrease drastically, in terms of the decreasing proportion of pervasive deformation. All these variations are attributed to the oblique arc-continent collision that exhumed the whole accretionary prism and induced a local stress perturbation in southeastern Taiwan. 相似文献
15.
Nicole Bethoux Monica Segovia Viviana Alvarez Jean-Yves Collot Philippe Charvis Audrey Gailler Tony Monfret 《Journal of South American Earth Sciences》2011,31(1):139-152
A seismic study of a segment of the convergent margin of Ecuador is presented. During the SISTEUR campaign a network of 24 Ocean Bottom Seismometers (OBS) was deployed on the Carnegie Ridge, one line along the main axes of the ridge and two lines across the strike of the edge of the ridge, during one month. This marine network was complemented with a land network of 20 stations distributed in two lines: one parallel to the margin and the other perpendicular to it.The seismic event recorded by these networks, were located using different crustal models defined from the wide-angle seismic data modeling. Relative location techniques were used to improve earthquake locations. Seismogram waveform modeling allowed us to constrain hypocentral location for events farther than ~50 km from the network. This modeling also provided additional information to constrain the focal mechanisms of these events. The upper limit of the Interplate Seismogenic Zone (ISZ) is estimated to be at a 10 km depth in the region. The background seismic activity of the upper plate provided new insights:1) A seismic cluster that reaches the base of the overriding plate is linked to the Jipijapa-Portoviejo fault. The reactivation of this Quaternary fault is confirmed by focal mechanisms that provide rupture planes parallel to its superficial projection (N10°–N25°).2) The focal mechanisms presented in this study are compatible with a homogeneous regional stress field corresponding to an E–W to ESE–WNW compression and an NNE–SSW extension. The presence of strike-slip deformation, with a reverse component, corresponds to the NNE escape of the North Andean Block. Normal faulting accommodating this movement suggests that this part of the North Andean Block cannot be considered as a rigid block. 相似文献
16.
《Journal of African Earth Sciences》2010,57(4-5):167-178
Deformed conglomeratic clasts exposed along the Neoproterozoic Nakasib Suture and the Oko Shear Zone are used to calculate three-dimensional (3D) tectonic strain associated with the latter to quantify strain associated with post-accretionary deformational belts in the Arabian–Nubian Shield. The Nakasib Suture is a NE-trending fold and thrust belt that is sinistrally offset (∼10 km) by the cross-cutting NNW- to NW-trending strike-slip faults of the Oko Shear Zone. The Nakasib Suture was formed as a result of collision between the Haya terrane and the Gebeit terrane at ∼750 Ma ago. The Oko Shear Zone was subsequently formed as a result of an E–W directed shortening of the Arabian–Nubian Shield due to collision between East and West Gondwana at ∼670–610 Ma ago. This analysis indicates the following: (1) The Nakasib Suture is dominated by flattening strain with the flattening plane of the associated strain ellipsoid oriented at 21°/77°SE. This flattening deformation is interpreted to be associated with nappe emplacement from north to south. (2) Some regions along the Nakasib Suture are characterized by constriction strain that might be due to refolding of the early nappes about NE-trending axes. (3) The Oko Shear Zone is characterized by constriction strain, with the XY plane of the strain ellipsoid oriented at 171°/68°E. The strain ellipsoid associated with the Oko Shear Zone manifests superimposition of E–W shortening on the NE-trending fold and thrust belt associated with the Nakasib Suture. (4) The tectonic strain of the Oko Shear Zone, superimposed over the structures of the Nakasib Suture, is characterized by a strain ellipsoid whose flattening plane is oriented at 21°/49°W. The strain ellipsoid of the tectonic strain has a major axis with a quadratic elongation of 3.6 and an orientation of 357°/25°, an intermediate axis with a quadratic elongation of 1.2 and an orientation of 231°/30°, and a minor axis with a quadratic elongation of 0.25 and an orientation of 115°/18°. This suggests that the post-accretionary deformation of the Arabian–Nubian Shield was superimposed as a NW–SE directed shortening that created early N–S shortening zones and late NW-trending sinistral strike-slip faults. 相似文献
17.
马脑壳金矿床构造变形复杂且研究薄弱,作者通过野外地质填图并结合矿山生产勘探,以构造解析为研究方法,对马脑壳金矿床的变形特征与金成矿关系进行了研究。构造解析表明区内地层在成岩期遭受了同生变形,成岩后先后遭受了NE-SW向的挤压褶皱逆冲变形([T33])、左行走滑变形并伴随伸展塌陷变形(J1-2),宏观上表现为推覆—走滑控矿,即印支末期推覆作用形成的变形样式整体控制着金矿体的产出和分布,后期走滑作用叠加改造导致的张性破裂样式控制着金矿化强度,成矿作用主要发生在左行走滑变形阶段(J1-2),成矿机制是燕山早中期(J1-2)西秦岭地区由强烈的挤压动力体制向弥散间隔密集的走滑动力体制转换,导致含矿热液沿构造薄弱带(如区内F2断裂)上升迁移并在构造动力体制转换强烈的区域发生大规模金沉淀。西秦岭地区和松潘—甘孜地区的微细浸染型金矿极有可能形成于燕山早期(J1-2)由挤压向走滑构造动力体制转过程中。 相似文献
18.
西准噶尔达拉布特断裂带中段晚古生代构造分析 总被引:2,自引:0,他引:2
走滑断裂构造在中亚造山带增生及演化过程的研究中扮演了重要角色,其主要构造单元均被走滑断裂带所分割。西准噶尔造山带是中亚增生型造山带的重要组成部分,达拉布特断裂是西准噶尔造山带中一条重要的走滑断裂,其复杂的构造表现吸引了大量研究者的关注。前人不仅在其构造解释上存在着走滑断层、逆冲断层或压扭性断层等诸多争议,且在其活动时代问题上也有不同的看法。本文依据在达拉布特断裂带中段开展的详细野外构造学工作,结合前人针对该地区石炭纪火山岩、浊积岩和造山后花岗岩侵入体所做的同位素年代学工作成果,对达拉布特断裂的活动性质和活动时代进行了讨论。结果确认在中二叠统沉积之前,达拉布特断裂带存在两期变形事件,分别对应于320Ma左右沿NE-SW的较深层次的左行走滑事件D1和表现为脆-韧性转换域的轴面倾向SE的褶皱作用构造事件D2。前者为主期变形事件,而后者发生在中二叠统沉积之前。本文同时报道了沿达拉布特断裂带出露右行走滑构造形迹,并讨论了其可能的成因。沿达拉布特断裂带的多期构造事件记录了西准噶尔地区造山后大规模走滑构造调整过程,是晚古生代晚期中亚各个陆块拼合后大规模陆内调整在西准噶尔造山带的具体体现。 相似文献
19.
This study highlights the usefulness of anisotropy of magnetic susceptibility data from a deformed granitoid in deciphering its kinematic evolution vis-à-vis shear zone. Data are presented from the Chakradharpur Granitoid (CKPG) that lies to the north of the northerly dipping, ENE–WSW striking Singhbhum Shear Zone (SSZ; eastern India). Whilst the foliation recorded in the field in some parts of the granitoid is parallel to the SSZ, the magnetic foliation is N54°E/90° (mean orientation). It is suggested that the magnetic fabric provides a window into an evolutionary stage prior to the final shearing/thrusting event, the evidence of which is preserved on the mesoscopic scale. It is envisaged that during the initial stages of deformation there was simple shear along the evolving SSZ that resulted in sinistral strike-slip movement; the vorticity axis at this stage was steeply plunging and sense of rotation was anticlockwise. Space was generated in a direction ∼N25°E (perpendicular to maximum-Instantaneous Stretching Axis) into which CKPG emplaced synchronously with regional deformation and evolving SSZ. With continued deformation, there was thrusting along the SSZ. The vorticity axis flipped to a sub-horizontal orientation, thus leading to the development of down-dip stretching lineations and sheath folds within the SSZ. However, at the same time, the vorticity axis responsible for fabric evolution within the syntectonically crystallizing/cooling CKPG was steeply plunging with clockwise rotation. The magnetic foliation (mean orientation N54°E/90°) developed during the final stage of syntectonic crystallization. However, deformation in the region and thrusting along the SSZ continued even after the CKPG had fully crystallized and solidified, which led to the development of the ENE–WSW striking mesoscopic foliation that is parallel with the SSZ. We propose that the angle between the magnetic foliation and the SSZ/foliation recorded in the field, enables to decipher the kinematic vorticity number of flow responsible for fabric evolution of the CKPG. It is concluded that transpression was an important mechanism, and during regional deformation, whilst the SSZ developed structures by dominantly simple shear, the CKPG underwent dominantly pure shear. 相似文献
20.
《Geodinamica Acta》2000,13(2-3):67-85
The structure of western Provence (SE France) is the result of successive deformations connected to the building of the Pyrenees and the Alps. It is a seismically active region still undergoing deformation. The aim of this study is to characterize the recent deformation in western Provence and to integrate the cumulated displacements in a coherent deformation model. In order to do this, we identified the recent structures that concentrate the deformation. We used the Miocene as a sedimentary marker to estimate the discontinuous deformation over the last 20 Ma and geomorphic surfaces to evaluate the amount of the post-Miocene deformation. Miocene terrains are deformed along south-vergent thrusts such as Le Luberon, Les Costes, La Trévaresse or Les Alpilles, and along sinistral strike-slip faults such as the Durance and Nîmes faults. North-vergent Pyrenean thrusts such as L’Étoile-Sainte Baume, Sainte Victoire or the Eguilles thrusts were not reactivated during the Alpine phase. Field evidence shows that in the Luberon, the main folding phase occurred during, or immediately after the Burdigalian (20.5–16 Ma). The shortening measured on a regional N–S cross-section is of a few kilometres, implying a deformation of 0.1–0.2 mm·year–1 since the beginning of the Miocene. Geomorphic surfaces have been reported on cross-sections of the E–W thrusts. The intensity of the deformation decreases southward and through time during the Miocene. Pliocene surfaces are not deformed near the active structures, except at the front of the Digne thrust. Furthermore, Quaternary geomorphic markers such as alluvial fans are not affected by the Durance strike-slip fault. Our results show that from Miocene to the Present, Provence was not intensively deformed (0.1–0.2 mm·year–1), and occurred in a short period of time during the Miocene. It is coherent with the southward emplacement of the Alpine Digne thrust being the cause of this deformation. Since the end of the Miocene, there have been no major displacements on any of the active structures. 相似文献