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1.
山东鲁西地块断裂构造分布型式与中生代沉积—岩浆—构造演化序列 总被引:7,自引:0,他引:7
鲁西地块的断裂构造有两类不同分布型式:一类呈放射状分布, 由陡倾、基底右行韧性剪切带和盖层内复杂力学性质的断裂组成; 另一类呈环绕地块基底核部同心环状分布, 由3个主要盖层伸展拆离带组成, 主滑脱面分别位于古生界盖层与基底间的不整合面、石炭系与奥陶系之间的平行不整合面和中新生代断陷-沉积岩系与新生代火山-沉积物之间的断层。中生代构造变形样式可以分为3个层次:印支期褶皱-逆冲推覆构造、燕山中期NNE轴向的隔槽式箱状褶皱和燕山晚期NW、NNE向共轭正断-走滑断裂。相应地鲁西地块经历了3个成盆期, 即早-中侏罗世、早白垩世和晚白垩世, 这些中生代盆地在空间上的叠置导致了地块内部复杂的盆-山耦合关系。鲁西地块中生代有两个岩浆活动集中时期, 即早侏罗世(约190Ma)和早白垩世(132~110Ma)。综合沉积记录、岩浆活动和构造变形过程, 将鲁西地块中生代构造演化历史划分为6个阶段:晚三叠世挤压变形, 早、中侏罗世弱伸展作用, 中、晚侏罗世挤压变形与地壳增厚作用, 早白垩世大陆裂谷与地壳伸展作用, 早白垩世末期挤压变形与盆地反转事件和晚白垩世区域隆升。这些构造演化阶段和构造事件对研究和理解中生代构造体制和深部岩石圈动力学转换过程具有重要意义。 相似文献
2.
晚中生代福建沿海地区发育多期与古太平洋板块俯冲有关的岩浆活动和构造变形.福建泉州地区伸展构造变形主要表现为高角度正断层和低角度正断层或拆离断层, 古构造应力场反演指示其形成于NW-SE向伸展环境.锆石U-Pb年代学指示泉州地区发育4期岩浆活动, 分别为晚侏罗世(~155 Ma)、早白垩世中期(130~125 Ma)、早白垩世末期(~109 Ma)以及晚白垩世早期(~100 Ma之后).结合构造变形的切割关系和岩浆岩年代学, 长乐-南澳剪切带左旋韧性走滑形成于130~120 Ma, 而右旋脆性剪切形成于120~100 Ma之间.古太平洋板块向华南大陆之下的俯冲角度变化导致福建沿海地区发育晚中生代造山带.造山作用开始于早白垩世之初, 结束于早白垩世末期, 以大规模NW-SE向伸展构造发育为标志, 其从同造山挤压到后造山伸展的转换发生于~120 Ma. 相似文献
3.
Changes of Late Mesozoic Tectonic Regimes around the Ordos Basin (North China) and their Geodynamic Implications 总被引:4,自引:0,他引:4
A synthesis is given in this paper on late Mesozoic deformation pattern in the zones around the Ordos Basin based on lithostratigraphic and structural analyses. A relative chronology of the late Mesozoic tectonic stress evolution was established from the field analyses of fault kinematics and constrained by stratigraphic contact relationships. The results show alternation of tectonic compressional and extensional regimes. The Ordos Basin and its surroundings were in weak N-S to NNE-SSW extension during the Early to Middle Jurassic, which reactivated E-W-trending basement fractures. The tectonic regime changed to a multi-directional compressional one during the Late Jurassic, which resulted in crustal shortening deformation along the marginal zones of the Ordos Basin. Then it changed to an extensional one during the Early Cretaceous, which rifted the western, northwestern and southeastern margins of the Ordos Basin. A NW-SE compression occurred during the Late Cretaceous and caused the termination of sedimentation and uplift of the Ordos Basin. This phased evolution of the late Mesozoic tectonic stress regimes and associated deformation pattern around the Ordos Basin best records the changes in regional geodynamic settings in East Asia, from the Early to Middle Jurassic post-orogenic extension following the Triassic collision between the North and South China Blocks, to the Late Jurassic multi-directional compressions produced by synchronous convergence of the three plates (the Siberian Plate to the north, Paleo-Pacific Plate to the east and Lhasa Block to the west) towards the East Asian continent. Early Cretaceous extension might be the response to collapse and lithospheric thinning of the North China Craton. 相似文献
4.
The Yanshan Orogenic Belt is located in the northern part of the North China Craton (NCC), which lost ∼120 km of lithospheric mantle during Phanerozoic tectonic reactivation. Mesozoic magmatism in the Yanshan fold-and-thrust belt began at 195–185 Ma (Early Jurassic), with most of the granitic plutons being Cretaceous in age (138–113 Ma). Along with this magmatism, multi-phase deformational structures, including multiple generations of folds, thrust and reverse faults, extensional faults, and strike-slip faults are present in this belt. Previous investigations have mostly focused on geochemical and isotopic studies of these magmatic rocks, but not on the thermal history of the Mesozoic plutons. We have applied 40Ar/39Ar thermochronology to biotites and K-feldspars from several Lower Cretaceous granitic plutons to decipher the cooling and uplift history of the Yanshan region. The biotite 40Ar/39Ar ages of these plutons range from 107 to 123 Ma, indicating that they cooled through about 350 °C at that time. All the K-feldspar step-heating results modeled using multiple diffusion domain theory yield similarly rapid cooling trends, although beginning at different times. Two rapid cooling phases have been identified at ca. 120–105 and 100–90 Ma. The first phase of rapid cooling occurred synchronously with widespread extensional deformation characterized by the formation of metamorphic core complexes, A-type magmatism, large-scale normal faults, and the development of half-graben basins. This suggests rapid exhumation took place in an extensional regime and was a shallow-crustal-level response to lithospheric thinning of the NCC. The second phase of rapid cooling was probably related to the regional uplift and unroofing of the Yanshan Belt, which is consistent with the lack of Upper Cretaceous sediments in most of the Yanshan region. 相似文献
5.
The Kalaqin metamorphic core complex, located on the northern margin of the Yanshan Tectonic Belt, is an important structure to understand the Late Mesozoic destruction processes of the North China Craton. In this study, structural analysis and geochronological investigation were conducted for the Anjiayingzi pluton and associated granodiorite dikes that intruded the core complex. Field observations demonstrated that emplacement of the pluton and dikes took place after the early stage extensional deformation, and intrusions are products of syn-tectonic magmatism during the late stage extension deformation. LA-ICP-MS zircon U-Pb dating yielded ages of 133-131 Ma for the Anjiayingzi pluton and 135 Ma for the dike, which demonstrated that the early extensional deformation took place at 156-135 Ma, rather than the Early Cretaceous as proposed previously. By integrating with other dating results, the early extensional deformation occurred at 156-150 Ma (Late Jurassic) and led to the exhumation of the core complex. The core complex was overprinted by a late extension in the Early Cretaceous. The revision of formation time for the Kalaqin metamorphic core complex further confirms that the extensional deformation took place in the Late Jurassic in the Yanshan tectonic belt, and therefore, it is likely that the northern margin of the North China Craton might have destructed since the Late Jurassic. © 2018, Science Press. All right reserved. 相似文献
6.
The northern China–Mongolia tract exhibited a tectonic transition from contractional to extensional deformation in late Mesozoic time. Late Middle to early Late Jurassic crustal shortening is widely thought to have resulted from collision of an amalgamated North China–Mongolia block and the Siberian plate, but widespread late Late Jurassic–Early Cretaceous extension has not been satisfactorily explained by existing models. Some prominent features of the extensional tectonics of the northern China–Mongolia tract are: (1) Late Jurassic voluminous volcanism prior to Early Cretaceous large-magnitude rapid extension; (2) overlapping in time of contractional deformation in the Yinshan–Yanshan belt with development of extension-related basins in the interior of the northern China–Mongolia tract; and (3) widespread occurrence of alkali granitic plutonism, extensional basins and metamorphic core complexes in the Early Cretaceous. A new explanation is advanced in this study for this sequence of events. The collision of amalgamated North China–Mongolia with Siberia led to crustal overthickening of the northern China–Mongolia tract and formation of a high-standing plateau. Subsequent breakoff at depth of the north-dipping Mongol–Okhotsk oceanic slab is suggested as the main trigger for late Mesozoic lithospheric extension of that tract. Slab breakoff resulted in mantle lithospheric stretching of the adjacent northern China–Mongolia tract with subsequent ascent of hot asthenosphere and magmatic underplating at the base of the crust. Collectively, these phenomena triggered gravitational collapse of the previously thickened crust, leading to late Late Jurassic–Early Cretaceous crustal extension, and importantly, coeval contraction along the southern margin of the plateau in the Yinshan–Yanshan belt. The proposed model provides a framework for interpreting the spatial and temporal relationships of distinct processes and reconciling some seemingly contradictory phenomena, such as the synchronous extension of northerly terranes during major contraction in the neighboring Yanshan–Yinshan belt. 相似文献
7.
Wei Lin Michel Faure Yan Chen Wenbin Ji Fei Wang Lin Wu Nicolas Charles Jun Wang Qingchen Wang 《Gondwana Research》2013,23(1):54-77
With a cratonic nucleus, the North China Craton (NCC) experienced a complex tectonic evolution with multiphase compressional and extensional events during Mesozoic times. Along the northern part of the NCC, the Yinshan–Yanshan fold and thrust belt was a typical intraplate orogen. Jurassic and Cretaceous continental sedimentation, magmatism, widespread intraplate characterize the Yinshan–Yanshan orogenic belt. The geodynamic significance of these tectonic events is still in dispute. In the western part of the Liaoning province, the Yiwulüshan massif crops out at the eastern end of the Yinshan–Yanshan orogenic belt. The Yiwulüshan massif presents an elliptical domal shape with a NE–SW striking long axis. The structural evolution of this massif brings new insights for the understanding of the Mesozoic plutonic–tectonic history of the NCC. A multidisciplinary study involving structural geology, geochronology, Anisotropy of Magnetic Susceptibility (AMS) and gravity modeling have been carried out. The presentation of the new results splits into two parts. Part I (this paper) deals with field and laboratory structural observations, and presents the main geochronological results. The AMS, gravity modeling data will be provided in a companion paper (Part II). The early compressional deformation (D1) corresponds to a Late Jurassic to Early Cretaceous southward thrusting. The subsequent deformation is related to the Early Cretaceous exhumation of the Yiwulüshan massif. A detailed structural analysis allows us to distinguish several deformation events (D2, D3, and D4). The Cretaceous extensional structures, such as syntectonic plutons bounded by ductile normal faults, metamorphic core complexes, and half-graben basins are recognized in many places in East Asia. These new data from the Yiwulüshan massif constitute a link between Transbaikalia, Mongolia, North China and South China, indicating that NW–SE extensional Mesozoic tectonics occurred throughout the entire region. 相似文献
8.
9.
《International Geology Review》2012,54(13):1602-1629
Widespread Cretaceous volcanic basins are common in eastern South China and are crucial to understanding how the Circum-Pacific and Tethyan plate boundaries evolved and interacted with one another in controlling the tectonic evolution of South China. Lithostratigraphic units in these basins are grouped, in ascending order, into the Early Cretaceous volcanic suite (K1V), the Yongkang Group (K1-2), and the Jinqu Group (K2). SHRIMP U-Pb zircon geochronological results indicate that (1) the Early Cretaceous volcanic suite (K1V) erupted at 136–129 Ma, (2) the Yongkang Group (K1-2) was deposited from 129 Ma to 91 Ma, and (3) the deposition of the Jinqu Group (K2) post-dated 91 Ma. Structural analyses of fault-slip data from these rock units delineate a four-stage tectonic evolution of the basins during Cretaceous to Palaeogene time. The first stage (Early to middle Cretaceous time, 136–91 Ma) was dominated by NW–SE extension, as manifested by voluminous volcanism, initial opening of NE-trending basins, and deposition of the Yongkang Group. This extension was followed during Late Cretaceous time by NW–SE compression that inverted previous rift basins. During the third stage in Late Cretaceous time, possibly since 78.5 Ma, the tectonic stress changed to N–S extension, which led to basin opening and deposition of the Jinqu Group along E-trending faults. This extension probably lasted until early Palaeogene time and was terminated by the latest NE–SW compressional deformation that caused basin inversion again. Geodynamically, the NW–SE-oriented stress fields were associated with plate kinematics along the Circum-Pacific plate boundary, and the extension–compression alternation is interpreted as resulting from variations of the subducted slab dynamics. A drastic change in the tectonic stress field from NW–SE to N–S implies that the Pacific subduction-dominated back-arc extension and shortening were completed in the Late Cretaceous, and simultaneously, that Neo-Tethyan subduction became dominant and exerted a new force on South China. The ongoing Neo-Tethyan subduction might provide plausible geodynamic interpretations for the Late Cretaceous N–S extension-dominated basin rifting, and the subsequent Cenozoic India–Asia collision might explain the early Palaeogene NE–SW compression-dominated basin inversion. 相似文献
10.
《International Geology Review》2012,54(11):1417-1442
ABSTRACTThe Ordos Basin, situated in the western part of the North China Craton, preserves the 150-million-year history of North China Craton disruption. Those sedimentary sources from Late Triassic to early Middle Jurassic are controlled by the southern Qinling orogenic belt and northern Yinshan orogenic belt. The Middle and Late Jurassic deposits are received from south, north, east, and west of the Ordos Basin. The Cretaceous deposits are composed of aeolian deposits, probably derived from the plateau to the east. The Ordos Basin records four stages of volcanism in the Mesozoic–Late Triassic (230–220 Ma), Early Jurassic (176 Ma), Middle Jurassic (161 Ma), and Early Cretaceous (132 Ma). Late Triassic and Early Jurassic tuff develop in the southern part of the Ordos Basin, Middle Jurassic in the northeastern part, while Early Cretaceous volcanic rocks have a banding distribution along the eastern part. Mesozoic tectonic evolution can be divided into five stages according to sedimentary and volcanic records: Late Triassic extension in a N–S direction (230–220 Ma), Late Triassic compression in a N–S direction (220–210 Ma), Late Triassic–Early Jurassic–Middle Jurassic extension in a N–S direction (210–168 Ma), Late Jurassic–Early Cretaceous compression in both N–S and E–W directions (168–136 Ma), and Early Cretaceous extension in a NE–SW direction (136–132 Ma). 相似文献
11.
辽宁及其毗邻地区大地构造位置隶属于环太平洋构造带外带内陆区,该区分布有为数众多的中生代盆地.根据前晚三叠世基底出露情况,在该区划分出了61个中生代盆地.盆地的构造类型分为拗裂型、裂陷型、断陷型和断拗型4种类型.拗裂型盆地形成于晚三叠世-中侏罗世,又称早中生代盆地;断陷型和裂陷型盆地形成于晚侏罗世-早白垩世早期,又称晚中生代早期盆地;断拗型盆地形成于早白垩世晚期-晚白垩世,又称晚中生代晚期盆地.拗裂盆地与环太平洋深大断裂体系的热构造关系不明显,而与古板块构造的隆起和裂陷有关;裂陷和断陷盆地与环太平洋深大断裂体系的热构造密切相关,盆地严格受大兴安岭和下辽河-双辽两大热构造隆起带控制;断拗盆地与环太平洋弧后拉张的热体制有关. 相似文献
12.
Wei Lin Nicolas Charles Yan Chen Ke Chen Michel Faure Lin Wu Fei Wang Qiuli Li Jun Wang Qingchen Wang 《Gondwana Research》2013,23(1):78-94
Granitoids play an important role in deciphering both crustal growth and tectonic evolution of Earth. In the eastern end of the Yinshan–Yanshan belt of North China Craton, the Yiwulüshan massif is a typical region that presents the tectonic evolution features of this belt. Our field work on the host rocks has demonstrated two phases of opposite tectonics: compressional and extensional, however, the deformation is almost invisible in the intrusive rocks. To improve the understanding of the tectonic evolution of the Yiwulüshan massif and the Late Mesozoic tectonics of East Asia, a multidisciplinary study has been carried out. In this study, anisotropy of magnetic susceptibility (AMS) and gravity modeling have been applied on these Jurassic plutons (Lüshan, Jishilazi and Guanyindong), which intrude into the Yiwulüshan massif. According to laboratory measurements and microscopic observations on thin sections, the AMS of the Yiwulüshan massif is characterized by secondary fabrics, indicating that the intensive post solidus deformation has reset the (primary) magmatic magnetic fabrics. A relatively gentle NW dipping magnetic foliation has been identified with two distinct groups of magnetic lineations of N34°E and N335°E orientations, namely LM1 and LM2, relatively. Gravity modeling reveals a southward thinning of the massif with a possible feeding zone rooted in the northern part of the massif. Integrating all results from structural observation, geochronological investigation, AMS measurement and gravity modeling, two tectonic phases have been identified in the Yiwulüshan massif, posterior to the Jurassic (180–160 Ma) magmatism in the Yinshan–Yanshan area. The early one concerns a Late Jurassic–Early Cretaceous (~ 141 Ma) compressional event with a top-to-the-south to southwest sense of shear. The second one shows an Early Cretaceous (~ 126 Ma) NW–SE ductile extensional shearing. At that time, sedimentary basins widened and Jurassic plutons started to be deformed under post solidus conditions. In fact, the NW–SE trend of the maximum stretching direction is a general feature of East Asian continent during Late Mesozoic. 相似文献
13.
华南中生代大地构造研究新进展 总被引:33,自引:0,他引:33
华南地区中生代构造动力体制经历了从特提斯构造域向滨太平洋构造域的转换,由此产生了强烈的陆内造山作用和岩浆活动,形成了复杂构造组合的晚中生代陆内造山带和火成岩省。本项研究在下列几个方面取得了新的进展:(1)通过对雪峰山地区沅麻盆地的野外调查和构造测量,确定了该盆地晚中生代-早新生代5期构造应力场及其演替序列:中晚侏罗世近W—E向挤压、早白垩世NW—SE向伸展、早白垩世中晚期NW—SE向挤压、晚白垩世近N—S向伸展、古近纪晚期NE—SW向挤压。构造应力场方向的变化记录了不同板缘的动力作用对该区的影响。(2)识别了湖南地区晚古生代-早中生代海相地层中发育的横跨叠加褶皱构造,并基于地层接触关系和已有火成岩同位素年代学数据分析,认为该地区横跨叠加褶皱构造记录了中生代两期构造挤压和地壳增厚事件:早期近东西向褶皱构造是对三叠纪华南地块南北边缘大陆碰撞和增生作用的远程响应,晚期NE—NNE向褶皱构造则是对中晚侏罗世古太平洋板块向华南大陆之下低角度俯冲作用的变形响应。(3)对湖南衡山西缘拆离断裂带的变形结构和运动学特征进行了详细的调查和构造测量,确定了衡山变质核杂岩构造,并对拆离带中韧性剪切变形的钠长岩脉的锆石进行了SHRIMP U-Pb测年,从而确定了华南地区伸展构造的起始时代约137 Ma,即早白垩世早中期。(4)通过锆石U-Pb年代学测试分析,揭示了东南沿海长乐—南澳构造带早白垩世2期构造-岩浆事件:早期(147~135 Ma)表现为强烈的混合岩化作用和深熔作用形成的片麻状花岗岩、花岗片麻岩等;晚期(135~117 Ma)岩浆岩以含石榴子石花岗岩为主。这个结果表明东南沿海构造带是晚中生代陆缘造山带,造山作用可能起始于晚侏罗世,于早白垩世早中期(135 Ma)以来发生伸展垮塌。在上述研究结果的基础上,探讨了华南地区三叠纪"印支运动"和中、晚侏罗世"燕山运动"的表现及其产生的板块构造动力体制及其转换时代、早白垩世从挤压构造应力体制向伸展构造应力体制转变的时间节点。 相似文献
14.
The Blue Nile Basin, situated in the Northwestern Ethiopian Plateau, contains ∼1400 m thick Mesozoic sedimentary section underlain by Neoproterozoic basement rocks and overlain by Early–Late Oligocene and Quaternary volcanic rocks. This study outlines the stratigraphic and structural evolution of the Blue Nile Basin based on field and remote sensing studies along the Gorge of the Nile. The Blue Nile Basin has evolved in three main phases: (1) pre‐sedimentation phase, include pre‐rift peneplanation of the Neoproterozoic basement rocks, possibly during Palaeozoic time; (2) sedimentation phase from Triassic to Early Cretaceous, including: (a) Triassic–Early Jurassic fluvial sedimentation (Lower Sandstone, ∼300 m thick); (b) Early Jurassic marine transgression (glauconitic sandy mudstone, ∼30 m thick); (c) Early–Middle Jurassic deepening of the basin (Lower Limestone, ∼450 m thick); (d) desiccation of the basin and deposition of Early–Middle Jurassic gypsum; (e) Middle–Late Jurassic marine transgression (Upper Limestone, ∼400 m thick); (f) Late Jurassic–Early Cretaceous basin‐uplift and marine regression (alluvial/fluvial Upper Sandstone, ∼280 m thick); (3) the post‐sedimentation phase, including Early–Late Oligocene eruption of 500–2000 m thick Lower volcanic rocks, related to the Afar Mantle Plume and emplacement of ∼300 m thick Quaternary Upper volcanic rocks. The Mesozoic to Cenozoic units were deposited during extension attributed to Triassic–Cretaceous NE–SW‐directed extension related to the Mesozoic rifting of Gondwana. The Blue Nile Basin was formed as a NW‐trending rift, within which much of the Mesozoic clastic and marine sediments were deposited. This was followed by Late Miocene NW–SE‐directed extension related to the Main Ethiopian Rift that formed NE‐trending faults, affecting Lower volcanic rocks and the upper part of the Mesozoic section. The region was subsequently affected by Quaternary E–W and NNE–SSW‐directed extensions related to oblique opening of the Main Ethiopian Rift and development of E‐trending transverse faults, as well as NE–SW‐directed extension in southern Afar (related to northeastward separation of the Arabian Plate from the African Plate) and E–W‐directed extensions in western Afar (related to the stepping of the Red Sea axis into Afar). These Quaternary stress regimes resulted in the development of N‐, ESE‐ and NW‐trending extensional structures within the Blue Nile Basin. Copyright © 2008 John Wiley & Sons, Ltd. 相似文献
15.
胶莱盆地白垩纪构造应力场与转换机制 总被引:14,自引:3,他引:14
通过对胶莱盆地断层滑动矢量的收集与测量,利用计算机程序反演了盆地白垩纪的古构造应力场演化历史,并据此将盆地的发育划分为三个伸展阶段和三个挤压反转阶段,分别为早白垩世早-中期莱阳期伸展,与造山期后应力松弛重力坍塌有关;早白垩世中-晚期青山期伸展,受早白垩纪早期以后广泛的岩石圈减薄、大陆裂陷制约;晚白垩世王氏期伸展,与郯庐断裂及牟平-即墨断裂右旋走滑有关。三期伸展之间存在构造挤压反转,最后阐明各期盆地发育的地球动力学背景。 相似文献
16.
Ruth Soto Antonio M. Casas-Sainz Juan J. Villalaín Beln Oliva-Urcia 《Tectonophysics》2007,445(3-4):373-394
In this work we analyse and check the results of anisotropy of magnetic susceptibility (AMS) by means of a comparison with palaeostress orientations obtained from the analysis of brittle mesostructures in the Cabuérniga Cretaceous basin, located in the western end of the Basque–Cantabrian basin, North Spain. The AMS data refer to 23 sites including Triassic red beds, Jurassic and Lower Cretaceous limestones, sandstones and shales. These deposits are weakly deformed, and represent the syn-rift sequence linked to basins formed during the Mesozoic and later inverted during the Pyrenean compression. The observed magnetic fabrics are typical of early stages of deformation, and show oblate, triaxial and prolate magnetic ellipsoids. The magnetic fabric seems to be related to a tectonic overprint of an original, compaction, sedimentary fabric. Most sites display a NE–SW magnetic lineation that is interpreted to represent the stretching direction of the Early Cretaceous extensional stage of the basin, without recording of the Tertiary compressional events, except for sites with compression-related cleavage.Brittle mesostructures include normal faults, calcite and quartz tension gashes and joints, related to the extensional stage. The results obtained from joints and tension gashes show a dominant N–S to NE–SW, and secondary NW–SE, extension direction. Paleostresses obtained from fault analysis (Right Dihedra and stress inversion methods) indicate NW–SE to E–W, and N–S extension direction. The results obtained from brittle mesostructures show a complex pattern resulting from the superposition of several tectonic processes during the Mesozoic, linked to the tectonic activity related to the opening of the Bay of Biscay during the Early Cretaceous. This work shows the potential in using AMS analysis in inverted basins to unravel its previous extensional history when the magnetic fabric is not expected to be modified by subsequent deformational events. Brittle mesostructure analysis seems to be more sensitive to far-field stress conditions and record longer time spans, whereas AMS records deformation on the near distance, during shorter intervals of time. 相似文献
17.
对于喀喇沁变质核杂岩早白垩世构造过程与形成模式长期以来存在着不同的认识。通过详细的野外构造观察及擦痕应力场反演,并结合前人年代学数据,有效地制约了喀喇沁变质核杂岩早白垩世的构造演化,并对其形成模式进行了分析。结果表明,起源于晚侏罗世的喀喇沁变质核杂岩,在早白垩世(141~100 Ma)再次经历了强烈的伸展与岩浆活动。在此伸展活动中,沿着核部杂岩两侧分别发育了NE走向、倾向相反的楼子店-八里罕和上店-东风大型正断层,进而控制两侧半地堑式的小牛与平庄盆地的发育。在这两条边界断层的伸展运动及随后的均衡隆升中,核部杂岩不断抬升与剥露,先后发育了NE-NNE向的伸展韧性变形带与脆性正断层。这些早白垩世韧性和脆性伸展构造一致指示拉张方向为NW-SE向。综合分析表明,区内早白垩世伸展活动经历了141~134 Ma的初始伸展与同构造岩体侵位阶段、133~126 Ma的边界断层强烈活动与核部快速抬升阶段以及125~100Ma的均衡隆升阶段。喀喇沁变质核杂岩在早白垩世的伸展活动中转变为地垒式伸展穹窿,其强烈伸展活动出现在华北克拉通破坏峰期,动力学背景是古太平洋板块俯冲导致的远场弧后拉张。 相似文献
18.
华北东部中生代构造体制转折峰期的主要地质效应和形成动力学探讨 总被引:95,自引:10,他引:85
华北中生代构造体制转折始于 15 0~ 14 0Ma ,终于 110~ 10 0Ma ,峰期是 12 0~ 110Ma ,总体上是由挤压构造体制转化为伸展构造体制 ,由EW向转变为NNE向的盆岭构造格局。但是转折过程有复杂的细节和多次挤压与伸展的转变 ,边缘与克拉通内部、北缘与南 (东 )缘之间在时间和空间上也有一定的变化。南 (东 )缘的挤压构造以 2 30~ 2 10Ma为主 ,然后在 130~ 110Ma期间达到构造转折的剧变期。北缘则似乎表现出 2 30~ 2 10Ma和 180 ( 170 )~ 16 0 ( 15 0 )Ma两期挤压构造 ,130~ 110Ma是构造转折的峰期。盆地的演化有多样性 ,燕山地区前晚侏罗世时期呈现出北东东向褶皱逆冲带与挤压挠曲盆地带相邻并存的盆山结构 ;而后晚侏罗世时期呈现出北北东向裂谷盆地与断隆相间的盆岭结构 ;晚侏罗世后时期则呈现出北东—北北东向盆地与“活动”断隆相间 ,并受北东东向褶皱逆冲带控制的盆山结构。大别山南北隆升历史完全不同。深部结构的研究表明 ,华北东部的岩石圈在古生代末期已有减薄表现 ,在中生代急剧减薄 ,地幔和下地壳发生大规模置换 ,至 130~ 110Ma到达顶峰。新生代以来又有加厚的趋势。中生代构造转折不具典型造山带特征 ,可能与周围块体夹击引发的区域性大规模地幔隆起有关 相似文献
19.
燕山构造带北缘喀喇沁地区发育了晚古生代一中生代多期岩浆活动,记录了多期构造变形事件,是认识该构造带大地构造演化的理想地区。本文通过对该地区岩浆岩的系统定年及各期构造变形事件的研究,结合区域地质资料,综合分析了晚古生代一中生代的大地构造演化历史。分析结果表明,燕山构造带在早石炭世晚期一早二叠世处于古亚洲洋俯冲背景下的活动陆缘环境,出现了弧岩浆活动。中二叠世古亚洲洋沿索伦克缝合线关闭,使得燕山构造带成为周缘前陆挤压变形带,并对应着岩浆活动的平静期。之后燕山构造带分别出现了晚二叠世一三叠纪、中侏罗世、晚侏罗世与早白垩世4期伸展背景下的岩浆活动。在这些岩浆活动之间的平静期,先后发生了早侏罗世、晚侏罗世初、早白垩世初3期挤压事件。这些现象还表明,岩浆活动与构造演化具有明显的耦合关系,板内环境下岩浆活动发生在伸展背景中,而岩浆活动平静期多对应区域挤压活动。 相似文献
20.
满洲里-额尔古纳地区中生代花岗岩的锆石U-Pb年代学与岩石组合:对区域构造演化的制约 总被引:9,自引:0,他引:9
本文对满洲里地区灵泉盆地、包格德乌拉盆地及额尔古纳地区上护林盆地和恩和盆地及周边的原确定为古生代和中
生代的花岗质岩石进行了岩石学和锆石LA-ICP-MS U-Pb 年代学研究,以便揭示研究区中生代的构造演化历史。研究区内
12 个代表性花岗岩中的锆石均呈自形-半自形晶,显示出典型的岩浆生长环带,结合其较高的Th/U比值(0.31~3.63),暗
示其为岩浆成因。测年结果表明,该区中生代花岗质岩浆活动可划分成以下三期:(1)中三叠世岩浆活动,可进一步划分
成241 Ma 和229 Ma 两期岩浆事件,241 Ma 黑云母正长花岗岩和229 Ma 正长花岗岩的存在可能与古亚洲洋闭合后的伸展环
境有关;(2)早- 中侏罗世岩浆事件,可进一步划分成(180±5)Ma 和(171±2)Ma 两期岩浆事件,黑云母二长花岗岩-
正长花岗岩组合,结合其斑岩型Mo 矿的存在,反映研究区处于活动陆缘的构造背景,可能与蒙古- 鄂霍茨克洋的俯冲作用
有关;(3)早白垩世早期岩浆活动,可进一步划分成(140~150)Ma 和(134±2)Ma 两期岩浆事件,前者与区域内发育的
吉祥峰组火山岩形成时代相近,后者的火口充填型产状表明它们应是该期岩浆事件演化晚期的产物,该期岩浆事件在松辽
盆地以东地区的缺乏暗示它们形成于伸展环境,并与蒙古-鄂霍茨克缝合带的演化有关。 相似文献
生代的花岗质岩石进行了岩石学和锆石LA-ICP-MS U-Pb 年代学研究,以便揭示研究区中生代的构造演化历史。研究区内
12 个代表性花岗岩中的锆石均呈自形-半自形晶,显示出典型的岩浆生长环带,结合其较高的Th/U比值(0.31~3.63),暗
示其为岩浆成因。测年结果表明,该区中生代花岗质岩浆活动可划分成以下三期:(1)中三叠世岩浆活动,可进一步划分
成241 Ma 和229 Ma 两期岩浆事件,241 Ma 黑云母正长花岗岩和229 Ma 正长花岗岩的存在可能与古亚洲洋闭合后的伸展环
境有关;(2)早- 中侏罗世岩浆事件,可进一步划分成(180±5)Ma 和(171±2)Ma 两期岩浆事件,黑云母二长花岗岩-
正长花岗岩组合,结合其斑岩型Mo 矿的存在,反映研究区处于活动陆缘的构造背景,可能与蒙古- 鄂霍茨克洋的俯冲作用
有关;(3)早白垩世早期岩浆活动,可进一步划分成(140~150)Ma 和(134±2)Ma 两期岩浆事件,前者与区域内发育的
吉祥峰组火山岩形成时代相近,后者的火口充填型产状表明它们应是该期岩浆事件演化晚期的产物,该期岩浆事件在松辽
盆地以东地区的缺乏暗示它们形成于伸展环境,并与蒙古-鄂霍茨克缝合带的演化有关。 相似文献