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兴蒙造山区及邻区早白垩世盆地岩石地层格架
与沉积古地理演化 总被引:2,自引:0,他引:2
在重点梳理兴蒙造山区及其相邻地区早白垩世地层分布与沉积古地理特征的基础上,从地层沉积学角度探讨了研究区早白垩世沉积盆地特征。兴蒙造山区中东部在晚侏罗世巨厚粗碎屑沉积建造之上发育了巨厚的酸性-中性火山岩-火山碎屑岩与河流-湖泊相沉积岩系,构成中国东北部巨型NE向火山岩-沉积岩带。兴蒙造山区中东部早白垩世早中期以断陷(裂谷)盆地为主,古地貌以高地、河流和湖泊共存为特征,气候温湿且炎热,热河生物群萌生;早白垩世中晚期,北东向地壳强烈伸展并进一步向外围地区扩展,沉积盆地及充填建造和热河生物群也相应地向更广泛区域辐射发展。兴安岭-燕山沉积-火山岩带与古太平洋板块俯冲无关,板内软流圈上涌导致的区域性伸展是其主要的成因动力机制,也是中国东部早白垩世中晚期更大规模区域性伸展作用的序幕。兴蒙东部早白垩世晚期沉积盆地发育和古地理格局受Izanagi板块向亚洲大陆东部俯冲弧后伸展构造机制约束。 相似文献
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为了揭示华北北部晚侏罗世沉积盆地性质,对赤城-宣化盆地中土城子组沉积特征及盆缘构造进行了研究。通过对土城子组沉积特征研究表明,土城子组中-下部为一套河湖相沉积,上部为一套冲积扇粗碎屑沉积;土城子组砾岩成分系统统计分析显示,赤城盆地与宣化-下花园盆地具有相似岩屑岩性相旋回,反映源区具有相同或相近的蚀顶过程。研究区晚侏罗世盆地中土城子组充填特征及盆缘构造特征表明,土城子组形成于挤压构造背景,土城子组沉积时期盆地受控于盆缘逆冲断层。大地构造背景暗示,赤城-宣化盆地晚侏罗世-早白垩世期间,古太平洋板块向NW方向的俯冲作用与尚义-赤城断裂向南逆冲并伴随右旋走滑作用是土城子组沉积时期盆地格局形成的重要控制因素。 相似文献
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扬子北缘黄陵地区古构造应力场于晚中生代经历发生了重大转变,是扬子板块与华北板块在三叠纪碰撞造山之后陆内构造变形的体现。由黄陵背斜周缘晚中生代盆地充填记录所反映出这一变革的起始时间为中侏罗世晚期。早侏罗世-中侏罗世早期,盆地内沉积了以桐竹园组为代表的河流-湖泊相岩层,由沉积碎屑成分和古水流统计所得出的物源区为北部的秦岭地区,黄陵背斜上部可能也接受了碎屑沉积;中侏罗世晚期-晚侏罗世,沉积中心发生了改变,表现为仅仅在黄陵背斜西侧的秭归盆地内有所保存,沉积环境以曲流河到辫状河流和三角洲为主,物源区则局限于黄陵背斜;早白垩世初期,周坪盆地和宜昌盆地为沉积中心,近缘冲积扇和辫状河流体系占据主体,物源区依然为黄陵地区,两盆地在黄陵背斜南缘可能相连,黄陵背斜上部的原下侏罗统被剥蚀;早白垩世晚期-晚白垩世,远安盆地逐渐发育,盆地西缘为冲积扇-辫状河流体系,中、 东部则以曲流河-湖泊沉积环境为主体,并间有干旱沙漠环境。原型盆地再造结果显示,早侏罗世-中侏罗世早期盆地展布具有近东西向特点,古地貌总体呈现出北部为山脉、 南部为盆地的格局;中侏罗世晚期以来,盆地呈近南北向,黄陵背斜逐渐形成山脉,盆地位于其东西两侧。两期盆地沉积特征反映了扬子北缘古构造应力场由近南北向转变为近东西向的过程。 相似文献
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中新生代天山隆升及其南北盆地分异与沉积环境演化 总被引:5,自引:2,他引:3
明确中生代以来天山隆升的时间顺序、隆升范围,及其与南北两侧盆地的沉积环境演化之间的关系,是天山两侧准噶尔盆地、吐哈盆地与塔里木等盆地原型恢复研究的重要需求。通过分析天山南北主要盆地类型、沉积充填、古气候变化,物源属性、边缘相带迁移反映的物源区远近变化与古水流特征,以及大量磷灰石裂变径迹测年数据认为,中新生代天山主要存在晚三叠世-早侏罗世、晚侏罗世-早白垩世、晚白垩世-始新世、中新世-第四纪的四期阶段隆升。在此基础上,编制了早侏罗世早期-第四纪的天山隆升范围及其南北盆地的沉积环境演化图,表明天山的四阶段隆升控制了北疆与南疆盆地由早、中侏罗世统一泛湖盆至晚侏罗-早白垩世盆地开始分异,再到新近纪以来彻底分割成独立盆地的沉积演化过程。同时,明确了天山南北两侧各盆地储层、烃源岩及盖层的重要形成期与天山隆升的关系,对有效拓展油气勘探范围有所启示。 相似文献
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大别山北缘合肥盆地中,新生代构造演化 总被引:26,自引:3,他引:23
合肥盆地中、新生代经历了多次沉降和降升变化,侏罗系沉积作用分布于整个盆地,中、晚侏罗世盆地内地层遭受广泛剥蚀。白垩纪沉积物局限于盆地东部,最大剥蚀区在盆地东南部。下第三系沉积集中于断裂带控制的断陷盆地中,剥蚀主要在盆地东部和南部。根据南北向平衡剖面分析,早侏罗世盆地为南北挤压,晚侏罗世盆地拉张松驰形成东西向断层;白垩纪受东西向挤压,早第三纪为南北向拉张。东西向平衡剖面分析表明:在盆地内存在一条规模巨大的南北向巨型隆起,隆起形成干早白垩世早期延续到晚白垩世晚期。盆地经历了早侏罗世前挤压推覆,侏罗-白垩纪松驰下陷,白垩纪盆地西部及中部隆升,晚白垩世-早第三纪盆地受南北向拉张作用。形成北断南超的箕状断陷盆地;晚第三纪挤压降升。 相似文献
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准南前陆盆地燕山期构造活动及其成藏意义 总被引:8,自引:1,他引:7
准南前陆盆地燕山期盆地格局的演变、沉积中心有规律的迁移、沉积特征(与构造活动相关的砾岩及其分布)显示晚侏罗世—早白垩世早期、晚白垩世是准南前陆盆地燕山期构造活动相对活跃的时期。晚侏罗世—早白垩世早期的喀拉扎砾岩、白垩系清水河组底砾岩为一套形成于邻近高地附近的剥蚀产物或冲积产物,其分布特征及成因是晚侏罗世—早白垩世早期局部挤压和构造隆升较为活跃的产物,也是盆地边界萎缩、盆山格局发生变化的重要证据,同时天山明显隆升并导致天山南北早白垩世沉积环境的巨大差异。准南前陆盆地烃源岩大量生排烃、圈闭形成、油气运聚成藏与燕山期构造活动关系密切;燕山期发育的储层是准南前陆盆地的主要油气储层,晚侏罗世—早白垩世早期砂砾岩和不整合分布也在一定程度上控制了油气分布,是今后寻找有利隐蔽油气藏、岩性地层油气藏的重要目标之一;燕山期古构造及其形成时间与油气成藏期的良好匹配决定其油气成藏的有效性。 相似文献
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综合野外观测、地震反射、钻探标定及镜质体反射率、古地温等相关资料,分析羌塘盆地中部不同地区侏罗系海相沉积地层的埋藏史、热史和生烃史。结果显示,羌塘盆地万安湖地区、半岛湖背斜、阿木错地区、比洛错古油藏早侏罗世海相泥页岩在沉积之后,中、晚侏罗世埋深快速增加,镜质体反射率Ro随之增大,晚侏罗世早中期下侏罗统泥页岩镜质体反射率 R o增至05%,主力烃源岩进入生烃门限开始生烃;早白垩世早期145~143Ma侏罗系海相地层埋深、古地温和 R o达到极大值,比洛错油页岩开始早期生油,阿木错主力烃源岩进入第一期生烃高峰。早白垩世构造隆升及风化剥蚀导致侏罗系海相地层向上折返,埋深减小,晚白垩世和古近纪早期前陆凹陷和红层沉积导致侏罗系海相地层埋深增加。比洛错古油藏Toarcian期油页岩晚白垩世末期古地温和 R o达到最大值,~66Ma形成生烃高峰;阿木错地区Toarcian期含油泥页岩始新世中期~43Ma埋深达到最大值,形成第二期生烃高峰。 相似文献
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《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
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准噶尔盆地南缘侏罗纪沉积相演化与盆地格局 总被引:28,自引:4,他引:24
通过对准噶尔盆地南缘侏罗系5条剖面的沉积特征对比,结合钻井资料和地震资料,确定了准噶尔盆地南缘侏罗纪盆地边界、沉积相演化及盆地格局。头屯河剖面和后峡剖面的沉积相对比及古流向测量表明二者在早、中侏罗世形成于同一沉积体系。在早、中侏罗世,沉积相逐渐从以辫状河-三角洲-湖泊相为主过渡到以河流相-湖泊相为主,沉积水体逐渐变浅;其中三工河组沉积时期盆地沉积范围达到最大,西山窑组沼泽相发育,车排子-莫索湾凸起自西山窑组沉积时期开始形成;早、中侏罗世的盆地边界至少位于后峡以南附近,此时不存在地理分割明显的天山山脉。晚侏罗世-早白垩世早期,沉积相从辫状河-滨浅湖相为主迅速演变为以辫状河-冲积扇相为主。在此期间盆地边界明显向北迁移,天山山脉明显隆升并造就天山南北沉积环境的巨大差异,博格达山构成盆地南缘的又一重要物源体系。 相似文献
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《International Geology Review》2012,54(12):1528-1556
ABSTRACTThe intra-continental orogeny and tectonic evolution of the Mesozoic Yanshan fold-thrust belt (YFTB) in the northern North China Craton (NCC) have been strongly debated. Here, we focus on the Shangyi basin, located in the centre of the YFTB. An integrated analysis of sedimentary facies, palaeocurrents, clast compositions, and detrital zircon dating of sediments was adopted to determine the palaeogeography, provenance, basin evolution, and intra-continental orogenic process. The Shangyi basin comprises the well-exposed Early–early Middle Jurassic Xiahuayuan Formation and the Longmen Formation, and the Late Jurassic–Early Cretaceous Tuchengzi Formation. Based on the 18 measured sections, five facies associations – including alluvial fan, fluvial, delta, lacustrine, and eolian facies – have been identified and described in detail. The onset of the Shangyi basin was filled with fluvial, deltaic, and lacustrine deposits controlled by the normal fault bounding the northern basin, corresponding to the pre-orogeny. In the Middle Jurassic, the cobble–boulder conglomerates of alluvial fan, as molasse deposits, were compatible with the syn-orogeny of the Yanshan movement, which played a critical role in northern North China and even East Asia. After the depositional break in the Middle–Late Jurassic, the Shangyi basin, controlled by the normal fault present in the north of the basin, re-subsided and quickly expanded southward with thick sedimentation, which is correlative with the post-orogeny. Combined with A-type granites, metamorphic core complexes, mafic dikes, and rift basins of the Late Jurassic–early Early Cretaceous present in the northern NCC and Mongolia, significant extension was widespread in the northern NCC and even in northeast Asia. Moreover, vertical changes of provenance indicate that the Taihang Mountain and the Inner Mongolia palaeo-uplift (IMPU) present at the west and north of the basin, respectively, experienced uplift twice in the Middle–Late Jurassic and Early Cretaceous, resulting in a regional depositional break. 相似文献
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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
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YANG Minghui LI Liang ZHOU Jin JIA Huichong SUN Xiao GONG Ting DING Chao 《《地质学报》英文版》2015,89(5):1636-1648
The hydrocarbon potential of the Hangjinqi area in the northern Ordos Basin is not well known, compared to the other areas of the basin, despite its substantial petroleum system.Restoration of a depth-converted seismic profile across the Hangjinqi Fault Zone(HFZ) in the eastern Hangjinqi area shows one compression that created anticlinal structures in the Late Triassic, and two extensions in ~Middle Jurassic and Late Early Cretaceous, which were interrupted by inversions in the Late Jurassic–Early Early Cretaceous and Late Cretaceous, respectively.Hydrocarbon generation at the well locations in the Central Ordos Basin(COB) began in the Late Triassic.Basin modeling of Well Zhao-4 suggests that hydrocarbon generation from the Late Carboniferous–Early Permian coal measures of the northern Shanbei Slope peaked in the Early Cretaceous, predating the inversion in the Late Cretaceous.Most source rocks in the Shanbei Slope passed the main gas-migration phase except for the Hangjinqi area source rocks(Well Jin-48).Hydrocarbons generated from the COB are likely to have migrated northward toward the anticlinal structures and traps along the HFZ because the basin-fill strata are dipping south.Faulting that continued during the extensional phase(Late Early Cretaceous) of the Hangjinqi area probably acted as conduits for the migration of hydrocarbons.Thus, the anticlinal structures and associated traps to the north of the HFZ might have trapped hydrocarbons that were charged from the Late Carboniferous–Early Permian coal measures in the COB since the Middle Jurassic. 相似文献
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The contractional structures in the southern Ordos Basin recorded critical evidence for the interaction between Ordos Basin and Qinling Orogenic Collage. In this study, we performed apatite fission track(AFT) thermochronology to unravel the timing of thrusting and exhumation for the Laolongshan-Shengrenqiao Fault(LSF) in the southern Ordos Basin. The AFT ages from opposite sides of the LSF reveal a significant latest Triassic to Early Jurassic time-temperature discontinuity across this structure. Thermal modeling reveals at the latest Triassic to Early Jurassic, a ~50°C difference in temperature between opposite sides of the LSF currently exposed at the surface. This discontinuity is best interpreted by an episode of thrusting and exhumation of the LSF with ~1.7 km of net vertical displacement during the latest Triassic to Early Jurassic. These results, when combined with earlier thermochronological studies, stratigraphic contact relationship and tectono-sedimentary evolution, suggest that the southern Ordos Basin experienced coeval intense tectonic contraction and developed a north-vergent fold-and-thrust belt. Moreover, the southern Ordos Basin experienced a multi-stage differential exhumation during Mesozoic, including the latest Triassic to Early Jurassic and Late Jurassic to earliest Cretaceous thrust-driven exhumation as well as the Late Cretaceous overall exhumation. Specifically, the two thrust-driven exhumation events were related to tectonic stress propagation derived from the latest Triassic to Early Jurassic continued compression from Qinling Orogenic Collage and the Late Jurassic to earliest Cretaceous intracontinental orogeny of Qinling Orogenic Collage, respectively. By contrast, the Late Cretaceous overall exhumation event was related to the collision of an exotic terrain with the eastern margin of continental China at ~100 Ma. 相似文献
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大兴安岭─燕山地层分区中、新生代地层 总被引:1,自引:0,他引:1
对大兴安岭和燕山北部的中生代地层,进行了系统的总结。侏罗纪早中期为含煤地层,晚期为以兴安岭群为代表的火山堆积;白垩纪早期为火山-沉积含煤地层,晚期为红层。第三纪以二连盆地合大量哺乳动物群的杂色沉积为特征。 相似文献