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利用最新的重磁数据对冲绳海槽南部的基底构造进行了推断解释,研究表明,在冲绳海槽南部,莫霍面构造为一南北两端高,中间低的鞍状构造,地壳厚度在15.5~21 km之间变化.基底深度一般在4~6 km之间变化,表现为南段深度大,北段深度小,在北西向断裂系的作用下,基底局部构造大都成北西向展布,说明冲绳海槽早期的北东向带状构造受到了后期的北西向构造活动的强烈改造作用.在冲绳海槽南部发育有两条沿北北东向展布的火成岩带,一条分布在冲绳海槽扩张轴以东及琉球岛弧西侧下坡;另一条分布在冲绳海槽与琉球岛弧隆褶带的结合部位,火成岩主要是由北东向构造活动产生的,而与北西向断裂关系不密切. 相似文献
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以28口钻井、3条主干地震剖面最新解释成果资料为依据的构造沉降史恢复结果表明:琼东南盆地新生代存在三期快速沉降过程和一期缓慢沉降过程:第一期为始新世,第二期为渐新世—早中新世,第三期存在时空差异:在盆地西部乐东凹陷为晚中新世以来,在盆地中东部陵水凹陷和松南-宝岛凹陷为上新世以来;缓慢沉降过程亦存在时空差异,盆地西部中中新世沉降缓慢,盆地中东部中—晚中新世沉降缓慢.第一期快速沉降过程受东亚陆缘扩张和红河断裂左旋走滑共同影响,第二期快速沉降受南海海底扩张和红河断裂左旋走滑联合作用,第三期快速沉降主要受红河断裂右旋走滑控制,缓慢沉降过程与南海海底扩张停止以及红河断裂构造活动处于宁静阶段相耦合. 相似文献
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Study of focal mechanisms of earthquakes in the Near and Komandorsky Islands indicate that there are several distinct zones of tectonic activity. South of the Near Islands, normal faulting occurs in the trench east of 172°E and low-angle thrusting dominates the Aleutian ridge. Mechanisms indicate underthrusting as far west as Mednyy Island with strike-slip faulting restricted to the south and west of Beringa Island. A zone of northeast striking left-lateral faulting near 1645.°E is proposed to separate the Aleutian Ridge from Kamchatka Peninsula. This motion, as well as faulting north of the Komandorsky Islands, may be related to the existance of a buffer plate comprising the Aleutian Ridge in the Komandorsky Islands. Active subduction terminates near 173°E and the faulting north of the Komandorsky Islands may, in part, be due to the bouyancy of a remnant slab. Depth phase modelling indicates bulletin-reported depths are overestimated due to a misidentification of depth phases. 相似文献
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对川东弧形褶皱带北段、中段和南段的三条剖面,进行了7件样品的磷灰石裂变径迹(AFT)测试,结合前人已发表的4件样品,分析模拟了主要背斜的隆升-剥露热历史.结果表明川东弧形带主体构造变形时间为135→65 Ma,即早白垩世早期到晚白垩世晚期.进而建立并对比了三条剖面的构造变形时序,揭示出川东弧形带的三维构造扩展历史:(1) 平行于构造线走向,表现为从中心向两翼的构造扩展,弧形带中段的构造变形最早,起始时间为早白垩世早期(约135 Ma),北段和南段的变形较晚,起始时间为早白垩世晚期(约100 Ma);(2) 垂直于构造线走向,在弧形带北段和中段均表现为由东向西的构造扩展,而在弧形带南段,由于受到前缘华蓥山断裂的影响,表现为自西向东的变形时序.川东弧形带的三维构造扩展历史暗示了"弯山构造"的成因模式,以及华蓥山先存断裂对弧形构造的限制作用. 相似文献
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Samuel T. Peavy Cahit
oruh John K. Costain William J. Domoracki 《Journal of Geodynamics》2004,37(3-5):633
Two reflection seismic transects, one across the central Appalachians in Virginia and the other across the southern Appalachians in Georgia, reveal a significant contrast in mid- and lower crustal reflectivity from east to west. Data from east of the Blue Ridge geologic province in Virginia and to the east of the Inner Piedmont in Georgia show a highly reflective crust extending from the near-surface to the Moho, including zones of east-dipping reflections, a sub-horizontal reflection signature at 7 seconds, and a west-dipping Moho. Reflection seismic data from west of the Blue Ridge in Virginia and Inner Piedmont farther south are characterized by reflector geometries related to deformation above a master decollement, leading to classic ‘thin-skinned’ tectonic structures in the overlying allochthon, and few if any apparent structures in the underlying basement. The location of the Iapetan rifted margin, the preexistence of favorably oriented structures to the east of this point, and sub-horizontal weak zones within the lower Paleozoic shelf strata have played critical roles in the distribution of seismic reflector geometry. Seismic reflection signatures seen in the southeastern United States are a result of multiple episodes of deformation from the early Paleozoic through the middle Mesozoic. Oblique stresses during late Paleozoic time produced transpression that manifested itself as predominantly strike-slip faulting to the east of the Blue Ridge/Inner Piedmont. Onlapping lower Paleozoic shelf strata responded to tectonic stresses through thin-skinned deformation above a master decollement during the late Paleozoic Alleghanian orogeny, aided in part by sub-horizontal zones of weakness in the strata. This partitioning of strain was supported via tectonic buttressing provided by Precambrian continental crust that was little deformed in the Taconic orogeny. During the Alleghanian orogeny, the variations in Valley and Ridge deformational style between the central and southern Appalachians were controlled by the original shape of the continental edge. Further deformation during Mesozoic extension occurred to the east of the Precambrian rift margin in the region where favorably oriented faults were reactivated, leading to the rotation of the fault zones from more steeply dipping initial orientations, the merging of the mid-crustal reflection zone with the Moho, and the formation of Mesozoic basins and antiformal reflections in the seismic sections. 相似文献
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Sequence stratigraphy of Jurassic-Cretaceous boundary strata in Luanping,Northern Hebei,China 总被引:1,自引:0,他引:1
TIAN Shugang LIU Yongqing LI Peixian PANG Qiqing & NIU Shaowu . Institute of Geology Chinese Academy of Geological Sciences Beijing China . Shijiazhuang Economic College Shijiazhuang China . Tianjin Institute of Geology Mineral Resources Tianjin China 《中国科学D辑(英文版)》2004,47(7):607-617
Division and correlation of terrestrial J-K bound are a knotty-argued problem. The key to solving the problem is to find a deposition-continuous section. Owing to stratigraphic hiatus and organism-phylogeny break, we have been discussing the problem without any unitary criterion for several decades. Tectonic ac-tivities occurring strongly in the J-K transitional pe-riod caused commonly sedimentary omissions and frequently volcanic eruptions in northern Hebei Prov-ince, western Liaoning Prov… 相似文献
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基于甘肃省夏河县—陕西省靖边县剖面的8次人工地震初至波数据, 利用有限差分走时方法反演得到了沿该剖面长约650 km的上部地壳速度结构和结晶基底的深度分布. 反演结果显示: 海原构造区西侧的西秦岭—祁连山褶皱区上部地壳的横向非均匀性明显, 基底深度从1 km到5 km不等, 反映了褶皱区改造变形强烈的构造特征; 其东侧的鄂尔多斯盆地基底深度约为5—6 km, 其速度均匀、 稳定, 上地壳呈弱速度梯度特征; 海原构造区及海原弧形断裂带附近上部地壳的破坏变形最严重, 区内横向高低速相间分布. 综上可知, 海原构造区东西两侧上地壳结构的显著差异揭示了其结构复杂性的成因及其与地震活动性的关系. 相似文献
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A gravity survey on the scale of 1: 250 000 was carried out in Block L2 located in the Lamu basin of south‐east Kenya in order to study tectonic features and find out favourable petroleum prospects in the block. This paper, through data processing and synthetic interpretation of the measured gravity data in the block, discusses characteristics of the gravity field and their geological implications, determines the fault system and the basement depth, analyses features of the main strata, divides structure units and predicts favourable petroleum zones. In the block, the regional gravity anomaly is mainly caused by the inclined Moho surface that rises in the east and subsides in the west topographically and the Bouguer gravity anomaly primarily reflects the superimposition of the gravity effect derived from the Moho surface and the basement relief. Two groups of faults extending NW (NWW) and NE (NEE) respectively are dominant in the block and their activities resulted in the framework of east‐west zoning and south‐north blocking. The basement depth greatly changes in an alternative high and low pattern. The Permian‐Triassic, Jurassic and Tertiary strata are extensively developed, while the Cretaceous is only developed in the east of the block. Structurally, the block can be divided into five units, of which the Tana sag shows excellent source‐reservoir‐seal associations and is a favourable target for future petroleum exploration. 相似文献
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利用中国大陆东南缘四条北西向人工地震测深剖面的初至Pg波走时,使用有限差分层析成像方法反演剖面基底速度结构,并通过初始模型选取、射线数分布、走时拟合等手段分析结果的可靠度.研究结果表明,剖面表层速度比华北克拉通的地表速度高,闽东火山断拗带地表速度普遍高于西侧的闽西南坳陷带.相邻构造带的分界线两侧均有明显的速度横向变化,剖面东段的闽东火山断拗带内的东南沿海一带,速度变化较大,地层的褶皱变形要强于西段.基底埋深自西向东呈逐渐变浅的趋势,剖面东段的闽东火山断拗带基底起伏剧烈,基底深度与闽西南坳陷带相比较浅,与闽西北隆起带相比较深.西段的闽西北隆起带基底变化较为平缓,基底深度相对较浅;闽西南坳陷带基底深度明显加深,在龙岩新泉盆地内最深接近4 km.基底形态的起伏变化揭示出东南缘基底是坳陷与隆起并存的构造特征,与研究区近代的地质构造特征相吻合.邵武—河源、政和—大埔和长乐—诏安断裂带都切割基底,其中,政和—大埔断裂4 km深度下方有比较明显的低速异常带,结合本文以及现有的研究结果,进一步确认政和—大埔断裂是不同断块构造单元的分界. 相似文献
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利用最新的重磁数据对冲绳海槽北部的基底构造进行了推断解释.研究表明,在海槽内部主要发育两条火山带,一条为著名的吐噶喇火山链,由一系列活动的或休眠的串珠状展布的活火山岛构成;另一条沿海槽中央张裂轴分布,主要由孤立的海底火山构成.冲绳海槽的基底具有沿东西向凹-凸-凹相间的构造格局,深度在1 km~8 km之间变化,受吐葛喇断裂带的北部断裂F1的作用,第三系基底构造发生了显著变化,说明吐葛喇断裂带的北部断裂F1是一条构造转换带.莫霍面为一北北东向的向东倾伏的幔坡,地壳厚度由21 km减至18 km. 相似文献
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Tectonic contrast between the conjugate margins of the South China Sea and the implication for the differential extensional model 总被引:2,自引:0,他引:2
The extensional model of the South China Sea(SCS)has been widely studied,but remains under debate.Based on the latest high-quality multi-channel seismic data,bathymetric data,and other obtained seismic profiles,the asymmetric characteristics between the conjugate margins of the SCS are revealed and extensional model of the SCS margin is discussed further.Spatial variation of morphology,basement structure,and marginal faults are discovered among the SCS margin profiles.As for the NS-trending variation,the basement of northern margin displays in the shape of step downwards to the sea,while the basement of southern margin is composed of wide rotated and tilted blocks,without any obvious bathymetric change.The variation also exists in the development of marginal faults between the conjugate margins,and detachment fault system is identified on the southern margin.Along the southern margin from east to west,the Eastern and Southwestern Basins developed different structural units.Based on the tectonic contrast of the conjugate margins,differential extensional model is proposed to explain the spatial variation of the SCS structure,which introduces detachment faults controlling the evolution of the SCS.The upper crust above the detachment fault was deformed by simple shear,while the lower crust and upper mantle below the detachment fault was deformed by pure shear.Because of the different lateral transfer between the upper brittle faulting and the lower ductile extensional regions,there developed marginal plateau(Liyue basin)and outer rise(Zhenghe massif)on the lower plate margin of the Eastern Basin and the Southwestern Basin,respectively.The evolution of the present SCS may be influenced by the diachronous close of the paleo-SCS. 相似文献
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本文选取辽宁海城、 盖州地区(40°~41°N, 122°~123°E)作为研究区, 利用广义极性振幅技术(GPAT)方法, 反演得到研究区2012—2017年6月共184个地震震源机制解, 并利用Misfit角度分析震源机制一致性参数特征。 研究结果表明: ① 研究区地震震源机制解以走滑型和正断型为主。 海城地区地震震源机制解以NW—SE向节面的左旋走滑型和NWW向节面的正断型为主。 发震构造以NW向海城河断裂为主, NE向节面为主的地震可能受到NE向金州断裂带的控制。 ② 青石岭地区的发震构造为与九寨—盖县北段共轭的NW向未知断裂, 西海域的地震活动可能是NE向的雁式断裂和NW向共轭的未知断裂共同作用的结果。 ③ 震源机制一致性结果显示, 一致性增强后发生了震级相对较大的地震。 研究区的震源机制一致性较强, 表明该区域的应力较为集中。 但由于2016年以来活动趋于平静, 尚难以根据震源机制解一致性程度做出当前应力状态的判断。 相似文献
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通过与更早地震资料的对比, 研究了鲜水河断裂带, 川滇地壳块体东带、 西带, 松潘、 龙门山断裂带以及整个川滇地区较长时间尺度的地震活动盛衰交替性。 结果表明, 川滇东带北段(鲜水河断裂带)、 松潘、 龙门山地震带及川滇西带中段和南段(主要是红河断裂带)的地震活动具有明显的几十到百年尺度的盛衰交替性。 而川滇东带中南段(安宁河-则木河-小江断裂带)与川滇西带北段(金沙江断裂带)在上述地震带的平静期里, 中强以上地震频次明显减少, 但有个别7级以上强震发生。 这样, 整个川滇地区地震活动的盛衰交替性呈现一种比较复杂的阶段性特征: 伴随频繁中强震的强震活跃期与突发强震活动期交替出现。 值得注意的是, 川滇地区从19世纪末开始的伴随频繁中强震的强震活跃期已超过百年, 目前出现长期平静, 应注意进入突发强震活动期的可能性。 根据川滇地区上一个突发强震活动期突发强震的空间分布, 推测未来的突发强震可能发生在南北向断裂带, 或其他方向断裂带与南北向断裂带的交汇部。 文中还对上述统计现象的机理作了简要讨论。 相似文献
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Modern tectonic stress field in the Chinese mainland inverted from focal mechanism solutions 总被引:1,自引:0,他引:1
IntroductionTheinversionapproachofregionalstressfielddevelopedinrecent10to20yearsprovidesausefultoolforstudyingthemeanstressinagivenregion(Angeller,1979;Ellsworth,1981,Xu,Ge,1984).Becauseitusesmultitudinousfaultsinsteadofsinglefault,itcanremovetheinhomogeneityoflocalmediumsoastorevealtheregionalstressinformation.Besides,thismethodproducesaRvalue,whichisdefinedby(O-2--q)/(q--q),andmaydescribestherelativemagnitUdeofintermediateprincipalstress,whereq,acand%arethemaximum,theintermediateandthemi… 相似文献
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通过在玉溪盆地用地震反射法探测普渡河隐伏断裂的实例, 阐述了在覆盖层很厚、 人口密集、 环境干扰强条件下的地震勘探方法技术. 本次勘探针对场地条件使用了大型可控震源和小检波距、 长排列、 高覆盖次数的观测系统. 获得的高信噪比时间剖面清晰地揭示了玉溪盆地内普渡河断裂的产状和规模. 勘探结果表明, 玉溪盆地覆盖层(N+Q)最大厚度超过820 m; 基岩面西陡东缓, 呈北北东走向的箕状分布; 普渡河断裂分两支穿过玉溪盆地西部, 主断裂为正断性质, 走向约N20°E, 倾向东, 视倾角75°—80°; 断裂规模由南向北逐渐变大, 基岩断距在盆地南部的大营街附近为40 m, 而在盆地北部的九龙池东部, 基岩断距增加到280 m左右, 穿过玉溪盆地西部的普渡河断裂错断了新近系上新统中上部地层. 相似文献
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对于羌塘盆地是否存在横贯东西的中央隆起带,目前学术界仍有分歧.本文提供的最新高精度航空重、磁资料证实存在呈东西向贯通羌塘盆地的中央隆起带,并对该带的构造特征进行了精细刻画.隆起带受南北两侧深大断裂控制,其空间跨度(宽度)由西向东逐渐收敛,并被一组近南北向的隐伏断裂系切割、左滑错动.重、磁场资料还显示中央隆起带在双湖东、西两侧存在明显差异:西段基底大规模隆起,基岩深度一般在3~5 km以内,明显浅于南北羌塘坳陷7~15 km的基底埋深;东段基底隆起幅度明显降低,主要表现为潜伏的低隆起,其中双湖—雅曲段基底埋深5~7 km,雅曲—岗尼段基底埋深7~9 km;即中央隆起带基底自西向东"台阶状"降低,隆起的幅度和分布范围受到近南北向断裂控制.构造分层表明,与南羌塘地块相比,北羌塘地块的基底隆起幅度小、稳定性更好.南北羌塘基底地球物理属性的显著差异说明羌塘盆地并不存在统一的前寒武系变质基底,中央隆起带的形成应该与古特提斯洋关闭时形成的混杂岩带有关. 相似文献
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Back-arc rifting in the Izu-Bonin Island Arc: Structural evolution of Hachijo and Aoga Shima Rifts 总被引:1,自引:0,他引:1
Adam Klaus Brian Taylor Gregory F. Moore Fumitoshi Murakami Yukinobu Okamura 《Island Arc》1992,1(1):16-31
Abstract Multi- and single-channel seismic profiles are used to investigate the structural evolution of back-arc rifting in the intra-oceanic Izu-Bonin Arc. Hachijo and Aoga Shima Rifts, located west of the Izu-Bonin frontal arc, are bounded along-strike by structural and volcanic highs west of Kurose Hole, North Aoga Shima Caldera and Myojin Sho arc volcanoes. Zig-zag and curvilinear faults subdivide the rifts longitudinally into an arc margin (AM), inner rift, outer rift and proto-remnant arc margin (PRA). Hachijo Rift is 65 km long and 20–40 km wide. Aoga Shima Rift is 70 km long and up to 45 km wide. Large-offset border fault zones, with convex and concave dip slopes and uplifted rift flanks, occur along the east (AM) side of the Hachijo Rift and along the west (PRA) side of the Aoga Shima Rift. No cross-rift structures are observed at the transfer zone between these two regions; differential strain may be accommodated by interdigitating rift-parallel faults rather than by strike- or oblique-slip faults. In the Aoga Shima Rift, a 12 km long flank uplift, facing the flank uplift of the PRA, extends northeast from beneath the Myojin Knoll Caldera. Fore-arc sedimentary sequences onlap this uplift creating an unconformity that constrains rift onset to ~1-2Ma. Estimates of extension (~3km) and inferred age suggest that these rifts are in the early syn-rift stage of back-arc formation. A two-stage evolution of early back-arc structural evolution is proposed: initially, half-graben form with synthetically faulted, structural rollovers (ramping side of the half-graben) dipping towards zig-zagging large-offset border fault zones. The half-graben asymmetry alternates sides along-strike. The present ‘full-graben’ stage is dominated by rift-parallel hanging wall collapse and by antithetic faulting that concentrates subsidence in an inner rift. Structurally controlled back-arc magmatism occurs within the rift and PRA during both stages. Significant complications to this simple model occur in the Aoga Shima Rift where the east-dipping half-graben dips away from the flank uplift along the PRA. A linear zone of weakness caused by the greater temperatures and crustal thickness along the arc volcanic line controls the initial locus of rifting. Rifts are better developed between the arc edifices; intrusions may be accommodating extensional strain adjacent to the arc volcanoes. Pre-existing structures have little influence on rift evolution; the rifts cut across large structural and volcanic highs west of the North Aoga Shima Caldera and Aoga Shima. Large, rift-elongate volcanic ridges, usually extruded within the most extended inner rift between arc volcanoes, may be the precursors of sea floor spreading. As extension continues, the fissure ridges may become spreading cells and propagate toward the ends of the rifts (adjacent to the arc volcanoes), eventually coalescing with those in adjacent rift basins to form a continuous spreading centre. Analysis of the rift fault patterns suggests an extension direction of N80°E ± 10° that is orthogonal to the trend of the active volcanic arc (N10°W). The zig-zag pattern of border faults may indicate orthorhombic fault formation in response to this extension. Elongation of arc volcanic constructs may also be developed along one set of the possible orthorhombic orientations. Border fault formation may modify the regional stress field locally within the rift basin resulting in the formation of rift-parallel faults and emplacement of rift-parallel volcanic ridges. The border faults dip 45–55° near the surface and the majority of the basin subsidence is accommodated by only a few of these faults. Distinct border fault reflections decreases dips to only 30° at 2.5 km below the sea floor (possibly flattening to near horizontal at 2.8 km although the overlying rollover geometry shows a deeper detachment) suggesting that these rifting structures may be detached at extremely shallow crustal levels. 相似文献