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1.
E.V. Artyushkov 《Russian Geology and Geophysics》2010,51(1):48-57
The large North Chukchi Basin in the northeastern Eurasian shelf is filled with up to 22 km of sediments, which is far thicker than filling a basin upon oceanic crust would require. The basin sedimentation began 380 Myr ago, and about 16 km of sediments have been deposited for the past 125 Myr, long after the oceanic crust would have completed its subsidence. This fact is in favor of the continental instead of oceanic crust origin. Rapid basin subsidence appears to be driven by a mechanism other than crustal stretching as the latter has no evidence over the greatest part of the basin area. The suggested basin formation model implies a transformation of gabbro into denser eclogite in the lower crust and related contraction of mafic rocks. To sustain consolidated crust beneath 22 km thick sediments, the layer of dense eclogites under the granitic layer must be at least ~25 km thick. The presence of basement flexures formed at several stages of the basin evolution indicates a considerable loss of lithospheric rigidity under the effect of fluid infiltration from small mantle plumes. The fluids catalyzed the eclogitization and thus increased the subsidence rate. Rapid subsidence apparently occurred in Barremian-Albian time when the basin had accumulated up to 11.5 km of sediments. Besides the Early Cretaceous event, there were, possibly several older events of rapid subsidence. This basin subsidence history, along with the evidence of steep lithospheric flexure, is a known feature of large petroleum basins. Therefore, the North Chukchi Basin may be expected to be an oil and gas producer. 相似文献
2.
洋-陆过渡带是理解大陆岩石圈破裂和海底初始扩张的关键位置,但是在南海北部地区仍然存在关于相关地质过程的诸多疑问.通过近年开展的国际大洋发现计划航次以及深部地质地球物理探测,取得以下4个方面的认识.(1)南海北部的洋-陆边界一般与自由空间重力异常的正-负值过渡位置对应,而更加准确地限定需要结合反射、折射地震资料.稳定大洋岩石圈生成与大陆岩石圈最终破裂之间的洋-陆过渡边界的位置比以往认为的还应往深海盆方向移动.(2)洋-陆过渡带代表了远端带构造作用减弱和岩浆作用逐渐增强的区域.陆坡地壳发育扩张后岩浆底侵、洋-陆过渡带发育同破裂期岩浆喷出结构和侵入反射体.(3)在中生代的古俯冲带弧前区域,新生代的断裂沿着早期的构造开始活动,岩石圈多处发生强烈的共轭韧性剪切作用.随着大陆岩石圈的进一步拉伸减薄,部分靠陆一侧的裂谷中心停止张裂,成为夭折裂谷,以台西南盆地南部凹陷、白云凹陷、西沙海槽为代表,而南海陆缘异常伸展和最终破裂的地方集中在南侧裂谷中心.夭折裂谷下亦发现地幔蛇纹石化,进一步反映了较弱的同破裂岩浆活动.(4)南海初始洋壳的增生沿着大陆边缘走向具有显著的变化,南海东北部洋-陆过渡带下伏地幔明显抬升和部分蛇纹石化,地震纵、横波速度以及折射波衰减特征都支持此观点,反映南海东北部是一个贫岩浆型大陆边缘.未来,南海北部洋-陆过渡带有望成为南海“莫霍钻”的理想备选钻探区. 相似文献
3.
We present results from a 484 km wide-angle seismic profile acquired in the northwest part of the South China Sea (SCS) during OBS2006 cruise. The line that runs along a previously acquired multi-channel seismic line (SO49-18) crosses the continental slope of the northern margin, the Northwest Subbasin (NWSB) of the South China Sea, the Zhongsha Massif and partly the oceanic basin of the South China Sea. Seismic sections recorded on 13 ocean-bottom seismometers were used to identify refracted phases from the crustal layer and also reflected phases from the crust-mantle boundary (Moho). Inversion of the traveltimes using a simple start model reveals crustal images in the study area. The velocity model shows that crustal thickness below the continental slope is between 14 and 23 km. The continental part of the line is characterized by gentle landward mantle uplift and an abrupt oceanward one. The velocities in the lower crust do not exceed 6.9 km/s. With the new data we can exclude a high-velocity lower crustal body (velocities above 7.0 km/s) at the location of the line. We conclude that this part of the South China Sea margin developed by a magma-poor rifting. Both, the NWSB and the Southwest Sub-basin (SWSB) reveal velocities typical for oceanic crust with crustal thickness between 5 and 7 km. The Zhongsha Massif in between is extremely stretched with only 6–10 km continental crust left. Crustal velocity is below 6.5 km/s; possibly indicating the absence of the lower crust. Multi-channel seismic profile shows that the Yitongansha Uplift in the slope area and the Zhongsha Massif are only mildly deformed. We considered them as rigid continent blocks which acted as rift shoulders of the main rift subsequently resulting in the formation of the Northwest Sub-basin. The extension was mainly accommodated by a ductile lower crustal flows, which might have been extremely attenuated and flow into the oceanic basin during the spreading stage. We compared the crustal structures along the northern margin and found an east-west thicken trend of the crust below the continent slope. This might be contributed by the east-west sea-floor spreading along the continental margin. 相似文献
4.
An interpretation of deep seismic sounding measurements across the ocean-continent transition of the Red Sea-Saudi Arabian Shield is presented. Using synthetic seismograms based on ray tracing we achieve a good fit to observed traveltimes and some of the characteristic amplitudes of the record sections. Crustal thickness varies along the profile from 15 km in the Red Sea Shelf to 40–45 km beneath the Asir Mountains and the Saudi Arabian Shield. Based on the computation of synthetic seismograms our model requires a velocity inversion in the Red Sea-Arabian Shield transition. High-velocity oceanic mantle material is observed above continental crust and mantle, thereby forming a double-layered Moho. Our results indicate a thick sedimentary basin in the shelf area, and zone of high velocities within the Asir Mountains (probably uplifted lower crust). Prominent secondary low-frequency arrivals are interpreted as multiples. 相似文献
5.
L.F. Sarmiento-Rojas J.D. Van Wess S. Cloetingh 《Journal of South American Earth Sciences》2006,21(4):383
Backstripping analysis and forward modeling of 162 stratigraphic columns and wells of the Eastern Cordillera (EC), Llanos, and Magdalena Valley shows the Mesozoic Colombian Basin is marked by five lithosphere stretching pulses. Three stretching events are suggested during the Triassic–Jurassic, but additional biostratigraphical data are needed to identify them precisely. The spatial distribution of lithosphere stretching values suggests that small, narrow (<150 km), asymmetric graben basins were located on opposite sides of the paleo-Magdalena–La Salina fault system, which probably was active as a master transtensional or strike-slip fault system. Paleomagnetic data suggesting a significant (at least 10°) northward translation of terranes west of the Bucaramanga fault during the Early Jurassic, and the similarity between the early Mesozoic stratigraphy and tectonic setting of the Payandé terrane with the Late Permian transtensional rift of the Eastern Cordillera of Peru and Bolivia indicate that the areas were adjacent in early Mesozoic times. New geochronological, petrological, stratigraphic, and structural research is necessary to test this hypothesis, including additional paleomagnetic investigations to determine the paleolatitudinal position of the Central Cordillera and adjacent tectonic terranes during the Triassic–Jurassic. Two stretching events are suggested for the Cretaceous: Berriasian–Hauterivian (144–127 Ma) and Aptian–Albian (121–102 Ma). During the Early Cretaceous, marine facies accumulated on an extensional basin system. Shallow-marine sedimentation ended at the end of the Cretaceous due to the accretion of oceanic terranes of the Western Cordillera. In Berriasian–Hauterivian subsidence curves, isopach maps and paleomagnetic data imply a (>180 km) wide, asymmetrical, transtensional half-rift basin existed, divided by the Santander Floresta horst or high. The location of small mafic intrusions coincides with areas of thin crust (crustal stretching factors >1.4) and maximum stretching of the subcrustal lithosphere. During the Aptian–early Albian, the basin extended toward the south in the Upper Magdalena Valley. Differences between crustal and subcrustal stretching values suggest some lowermost crustal decoupling between the crust and subcrustal lithosphere or that increased thermal thinning affected the mantle lithosphere. Late Cretaceous subsidence was mainly driven by lithospheric cooling, water loading, and horizontal compressional stresses generated by collision of oceanic terranes in western Colombia. Triassic transtensional basins were narrow and increased in width during the Triassic and Jurassic. Cretaceous transtensional basins were wider than Triassic–Jurassic basins. During the Mesozoic, the strike-slip component gradually decreased at the expense of the increase of the extensional component, as suggested by paleomagnetic data and lithosphere stretching values. During the Berriasian–Hauterivian, the eastern side of the extensional basin may have developed by reactivation of an older Paleozoic rift system associated with the Guaicáramo fault system. The western side probably developed through reactivation of an earlier normal fault system developed during Triassic–Jurassic transtension. Alternatively, the eastern and western margins of the graben may have developed along older strike-slip faults, which were the boundaries of the accretion of terranes west of the Guaicáramo fault during the Late Triassic and Jurassic. The increasing width of the graben system likely was the result of progressive tensional reactivation of preexisting upper crustal weakness zones. Lateral changes in Mesozoic sediment thickness suggest the reverse or thrust faults that now define the eastern and western borders of the EC were originally normal faults with a strike-slip component that inverted during the Cenozoic Andean orogeny. Thus, the Guaicáramo, La Salina, Bitúima, Magdalena, and Boyacá originally were transtensional faults. Their oblique orientation relative to the Mesozoic magmatic arc of the Central Cordillera may be the result of oblique slip extension during the Cretaceous or inherited from the pre-Mesozoic structural grains. However, not all Mesozoic transtensional faults were inverted. 相似文献
6.
7.
秦岭造山带作为典型的陆内复合造山带,发生过强烈的构造变形,与北部的渭河地堑形成独具特色的盆山构造体系,目前其深部结构状态与盆山耦合响应缺乏深层动力学过程的理解,为此以跨越秦岭造山带、渭河地堑布设一条170 km的大地电磁测深剖面,通过宽频带和长周期大地电磁观测,构建秦岭造山带和渭河地堑深部地电结构,研究结果表明:1)秦岭造山带存在多重叠置的巨厚岩石圈,南秦岭与北秦岭地壳尺度存在明显的结构化差异; 2)扬子地块向北楔入到南秦岭岩石圈地幔中,南、北秦岭之间在上地幔存在低阻条带痕迹表明了楔入作用的前缘位置; 3)渭河地堑存在巨厚的沉积盖层,厚度由南向北逐渐减薄,由南侧的7~8 km减到北侧的3~4 km。渭河地堑下地壳至上地幔区域分布的两个低阻块体表明其岩石圈存在明显的电性差异,这种差异性的存在表征了华北地块南向挤压作用背景下软流圈上涌的贡献。 相似文献
8.
The continental rise, slope, and shelf in the Beaufort Sea off northern Alaska were surveyed with 5600 km of common-depth-point (CDP) seismic data by the U.S. Geological Survey in 1977. The lower continental rise consists of a wedge of at least 4.5 km of low-velocity, generally flat-lying, parallel-bedded sediments. Slump-related diapiric folds, probably cored by shale, occur on the upper rise and lower slope. The observed minimum depth to oceanic basement in the Canada Basin requires an age for this basin of at least 120 m.y., assuming it to be floored by oceanic crust with a subsidence history similar to that of the Atlantic and Pacific oceans. 相似文献
9.
为揭示珠江口盆地西部陆缘伸展-减薄过程,进行盆地断裂构造样式识别、断层活动速率和一维空盆构造沉降定量计算和综合分析.珠江口盆地西部以铲式断层和拆离断层为主并继承性发育.张裂一幕断层活动和构造沉降集中于开平凹陷,最大速率分别达到239 m/myr和108.6 m/myr.张裂二幕断层活动和构造沉降向洋盆迁移,最大速率分别达到192 m/myr和210.7 m/myr.张裂一幕岩石圈减薄集中在开平凹陷,以地壳脆性薄化为主.张裂二幕减薄中心向洋盆迁移,岩石圈地幔可能发生了局部薄化和软流圈上涌,导致陆架和上陆坡区凹陷内部构造沉降减弱;洋陆过渡带处上地壳快速减薄,且薄化速度比下地壳快.对比西北次海盆南侧上地壳较厚及下地壳较薄或缺失的情况,推测西北次海盆在破裂前发生了不对称的单剪薄化. 相似文献
10.
桑托斯盆地盐下油气田中发现了大量CO2,给油气勘探开发和生产都带来诸多困难和挑战.利用地层测试、样品分析及文献资料等,明确了CO2成因及来源,统计分析了其区域分布特征,并基于区域重磁和深源地震等资料,剖析了控制CO2分布的地质因素.盆内CO2主要为幔源—岩浆成因,且幔源CO2贡献了至少92%的CO2总量.区域上,CO2自陆向海呈增加趋势,并相对集中在盆地东部隆起带上.地壳减薄和地幔局部隆升是控制CO2宏观分布最重要的背景因素.极端的地壳伸展造成了圣保罗地台下部陆壳强烈拉伸减薄,形成了一个面积约5.1×104 km2的地壳减薄区,造成了富含CO2的地幔物质上拱进入陆壳,宏观上决定了盆内CO2区域分布.此区域之外,出现高含量CO2的可能性大幅降低.岩浆侵入和活动断层都是沟通隆升地幔和浅部储层的重要路径,但以断裂沟通最常见.NW-SE向区域走滑断裂和NE-SW向I-II级正断层对CO2在浅部地层中的分配起控制作用,两组断裂交汇部位或周缘是幔源岩浆或CO2最集中发育区. 相似文献
11.
Zhen Sun Zhihong Zhong Myra Keep Di Zhou Dongsheng Cai Xushen Li Shimin Wu Jianqun Jiang 《Journal of Asian Earth Sciences》2009,34(4):544-556
The opening of the South China Sea is one of the most important Cenozoic events in SE Asia. In order to investigate its tectonic evolution, three analogue modeling experiments were compared. The modeling results suggest that rifting pattern and orientation change of the rift zone were related to initial rheological stratification. Affected by the ductile flow of silicone (lower crust) and honey (asthenosphere), the faults became flattened, especially close to the breakup area. We conjecture that the slope area may bear relatively hotter and thinner lithosphere than the shelf area from the beginning of rifting due to stretching and mantle upwelling associated with this regional extension, which in turn lead to the change in initial rheological stratification and therefore the rifting pattern from shelf to slope. In the experiments, breakup developed first at isolated points, which grew and coalesced to become a single spreading area. The conjugate boundaries were either all concave or all convex. Where a rigid massif was located at the divergent boundary, stretching history was different. In this case, the northern and southern areas thinned rapidly and developed into two deep troughs, which may finally evolve into spreading centers. The shape of the massif controls the orientation and boundary shape of the spreading area. It is interpreted that crustal breakup was more viscous in style, and the NW sub sea basin developed along the northern trough of the Zhongsha-Xisha massif (Macclesfield Bank). 相似文献
12.
During summer 1975, a line of large shots was fired across the continental margin between the Rockall Trough and the Hebridean shelf along 58°N. Arrivals were observed at temporary seismic stations set up across Scotland and in northwestern Ireland. A clear P2 phase was observed to cross the margin and a converted phase P1 also seen on the records is interpreted as travelling in the sub-sedimentary oceanic crust of Rockall Trough and in the upper continental crust beneath the shelf.The continental crust beneath the Hebridean shelf is estimated to be 27 ± 2 km thick, with Pg = 6.22 ± 0.03 km/s and Pn = 8.01 ± 0.04 km/s as determined by time-term analysis. Pg delays on the outer shelf are interpreted in terms of a seaward thickening wedge of Mesozoic sediments which pre-date the split. Pn beneath the Rockall Trough was poorly determined at 8.20 ± 0.17 km/s and the Moho is estimated to be 18 ± 2 km deep at 58°N. This and other seismic and gravity work indicates a northward thickening of the crust along the Rockall Trough, accounting for the northward decrease in the height of the slope.Our results, and those of gravity interpretations, indicate a relatively abrupt transition between continental and oceanic crust, possibly correlating with the lack of major shelf subsidence. This is attributed to a relatively cool origin for this margin. The main thinning of the continental crust beneath the slope is attributed to outslip of continental crustal material into and beneath the newly forming oceanic crust during the first few million years after the split, possibly enhanced by pre-split stretching. 相似文献
13.
洋壳厚度受多方面因素的影响,前人大多关注地幔温度、地幔源成分等岩石圈深部因素,很少关注岩石圈浅层的热液循环对洋壳厚度的影响。利用基于有限元的数值模拟手段,对扩张期不同背景(洋中脊、拆离断层)、不同扩张速率的热液循环与洋壳增生的关系进行研究。结果表明:洋壳增生达到稳定前,热液循环导致理论洋壳厚度发生阶段性减薄,减薄量随时间改变,并且推迟了上地幔中熔融体出现的时间;当洋壳增生达到稳定后,热液循环下产生的理论洋壳厚度反而比无热液循环的更厚。结合洋壳增生过程中对流热通量的变化分析,在洋壳增生前期的上地幔温度低,驱动热液循环的热源小,产生的对流热通量相对较小且不稳定,热液循环缓慢冷却上地幔顶部的温度,进而推迟上地幔初始熔融的时间,减弱上地幔的熔融,并造成一定时间阶段内的生成理论洋壳比正常理论洋壳厚度更薄;当洋壳增生达到稳定后,对流热通量达到最大并稳定,热液循环持续快速的冷却上地幔顶部温度,导致上地幔深部的热向上地幔顶部补给,反而增大了上地幔顶部的温度和熔融量,进而增大了理论洋壳厚度。随着扩张速率的增大,理论洋壳厚度增大,对流热通量增大,热液循环导致的洋壳阶段性减薄的最大减薄量也增大,阶段性减薄的时间缩短。结合南海西南次海盆的洋壳结构特征分析:两条横跨南海西南次海盆的地震剖面显示,海盆内存在异常薄的洋壳区域,并且两条地震剖面的最薄洋壳厚度相差0. 85 km,推测海盆内异常薄洋壳和不同扩张时期的最薄洋壳厚度差异受到扩张期热液循环阶段性减薄洋壳作用的影响。 相似文献
14.
Three long, strike-parallel, seismic-refraction profiles were made on the continental shelf edge, slope and upper rise off New Jersey during 1975. The shelf edge line lies along the axis of the East Coast Magnetic Anomaly (ECMA), while the continental rise line lies 80 km seaward of the shelf edge. Below the unconsolidated sediments (1.7–3.6 km/sec), high-velocity sedimentary rocks (4.2–6.2 km/sec) were found at depths of 2.6–8.2 km and are inferred to be cemented carbonates. Although multichannel seismic-reflection profiles and magnetic depth-to-source data predicted the top of oceanic basement at 6–8 km beneath the shelf edge and 10–11 km beneath the rise, no refracted events occurred as first arrivals from either oceanic basement (layer 2, approximately 5.5 km/ sec) or the upper oceanic crust (layer 3A, approximately 6.8 km/sec). Second arrivals from 10.5 km depth beneath the shelf edge are interpreted as events from a 5.9 km/sec refractor within igneous basement. Other refracted events from either layers 2 or 3A could not be resolved within the complex second arrivals. A well-defined crustal layer with a compressional velocity of 7.1–7.2 km/sec, which can be interpreted as oceanic layer 3B, occurred at 15.8 km depth beneath the shelf and 12.9 km beneath the upper rise. A well-reversed mantle velocity of 8.3 km/sec was measured at 18–22 km depth beneath the upper continental rise. Comparison with other deep-crustal profiles along the continental edge of the Atlantic margin off the United States, specifically in the inner magnetically quiet zone, indicates that the compressional wave velocities and layer depths determined on the U.S.G.S. profiles are very similar to those of nearby profiles. This suggests that the layers are continuous and that the interpretation of the oceanic layer 3B under the shelf edge east of New Jersey implies progradation of the shelf outward over the oceanic crust in that area. This agrees with magnetic anomaly evidence which shows the East Coast Magnetic Anomaly landward of the shelf edge off New Jersey and with previous seismic reflection data which reveal extensive outbuilding of the shelf edge during the Jurassic and Lower Cretaceous, probably by carbonate bank-margin accretion. 相似文献
15.
中国边缘海域及其邻区的岩石层结构与构造分析 总被引:3,自引:0,他引:3
利用中国边缘海域近年的地震层析成像结果,根据速度异常和各向异性分析东海、黄海和南海北部的岩石层结构和构造,讨论中朝块体和扬子块体在黄海内部的拼合边界(黄海东部断裂带)、东海陆架盆地上地幔异常与岩石层形成演化、南海北部地壳底部高速层的成因及地幔活动等问题。分析表明,黄海东部与朝鲜半岛之间存在一个深部构造界限(大致对应于黄海东部断裂带),分界两侧Pn波速度各向异性存在明显差异,反映不同构造应力和断裂剪切运动作用下的岩石层地幔变形特征。东海陆架下方的低速异常揭示了张裂盆地形成时期的地幔活动痕迹,表明中、新生代期间发生过地幔上涌并造成岩石层减薄,菲律宾海板块向西俯冲引发的地幔活动对东海陆架岩石层的形成、演化产生明显的影响。南海北部岩石层厚度较大并且温度相对偏低,地幔异常仅限于局部地区,估计南海北部大陆边缘的地壳底部高速层形成于张裂发生之前,或者是地壳形成时期壳幔分异时的产物。南海中央海盆的扩张不仅导致地壳拉张,软流层物质上涌,而且也造成岩石层地幔减薄甚至缺失。 相似文献
16.
第四纪最突出的事件是青藏高原和南海海盆的形成和演化。众多中外学者几乎一致认为,青藏高原的形成是由于印度克拉通向北的推动,南海等西太平洋边缘海是在太平洋板块和菲律宾海板块向西俯冲的过程中形成的。笔者另辟蹊径,提出,由于新生代(尤其是第四纪)以来两个相互交切的东亚断裂和南亚断裂的深部物理运动,使得南海等西太平洋边缘海地区的陆壳物质被逐渐吸入地幔,经转化为“幔源壳质”以后,再不断输送、补充给青藏地区。其结果必然是,南海等西太平洋边缘海地区的陆壳迅速转化为过渡型壳甚至洋壳,青藏地区则由洋壳转化为陆壳,并迅速隆起、增厚。 相似文献
17.
内蒙古小东沟斑岩型钼矿床的成矿时代及成矿物质来源 总被引:11,自引:0,他引:11
小东沟斑岩型钼矿床位于大兴安岭南段,距北部的西拉木伦河大断裂仅25 km。对小东沟岩体进行了Sr-Nd同位素和铅同位素分析,87Sr/86Sr(t)为0.705 0~0.705 5,εNd(t)为-2.4~-2.8;对主要钼矿体的6件辉钼矿样品进行了铼-锇同位素分析,所获同位素等时线年龄为(138.1±2.8)M a,表明小东沟钼矿床形成于早白垩世。铅同位素分析结果表明小东沟斑岩型钼矿床的成岩成矿物质具有不同来源,成岩物质来自俯冲洋壳衍生的新生地壳物质,而成矿物质来自地幔分异的产物(流体),属于壳源岩浆+幔源流体的组合。结合区域构造演化历史,对小东沟斑岩型钼矿的成因做出如下解释:在早白垩世,大兴安岭开始隆升,岩石圈拆沉,软流圈(层)物质上涌、基性岩浆的底侵以及地幔流体的加入,引起下地壳岩石的熔融,随后更多的地幔含矿流体进入到岩浆房。岩浆携带来自地幔的含矿流体,沿着区域性的EW、NE向深大断裂上侵定位,并在此过程中演化形成富硅、富钾质的花岗岩,最后沿近NS向的断裂侵位到二叠纪地层中,沉淀形成矿床。 相似文献
18.
为了揭示粤北地区岩石圈深部结构、深大断裂性质及花岗岩分布规律等科学问题,布设了乳源-潮州宽频带大地电磁探测剖面。由二维反演得出的电性结构,讨论了粤北地区岩石圈导电性结构特点。沿剖面存在3个花岗岩分布区,呈现不同的类型,可能代表不同的成因模式。沿剖面划分3条北东向断裂带:吉安-四会断裂、赣江断裂于韶关东形成宽度近20km的低阻区域,其间形成断陷盆地;河源-邵武断裂带,其两侧发育壳幔高导层并发育壳幔混合型花岗岩,深部电性结构复杂,可能为壳幔剧烈作用的场所;丽水-海丰断裂带,控制了燕山晚期花岗岩的分布。韶关、连平之间和龙川、丰顺之间50~150km存在2个巨大的低阻体,可能是地幔物质底侵作用的"通道";且底侵方向指向连平和龙川之间的区域,由于底侵作用力贡献,发育了一系列的壳内和上地幔高导层。粤北地区岩石圈从西向东逐渐减薄,从100余km减薄到60km,反映了太平洋板块对欧亚板块的消减作用。潮州100km深度以下的中-低阻特征,推断为太平洋板块俯冲作用留下的"洋壳"物质。 相似文献
19.
基于Advanced McKenzie地球动力学模型和Easy%RoDL化学动力学模型,建立了南黄海中-新生代(K13-Q)裂谷盆地的构造-热演化史,结合盆地深部壳幔结构、梳理周缘中-新生代板块汇聚与离散过程,讨论了该盆地低地热状态成因、成盆机制和烃源岩热演化.盆地地壳伸展系数约为1.22,岩石圈地幔伸展系数约为1.06;由裂陷期(K13-E2)至今,最高热流值仅由约76 mW/m2降低至约66 mW/m2,最高地温梯度仅由约37 ℃/km降低至约30 ℃/km,首次揭示低地热状态贯穿整个裂谷盆地发育阶段.低岩石圈地幔伸展系数、深部非镜像莫霍面分布、盆地发育阶段仅处于弧后远场拉张应力环境,均指示成盆过程中深部伸展上涌强度低,是导致其持续低地热状态的根本原因,深部热应力不是其主要成盆动力来源;依据高地壳伸展系数和控盆拆离断层演化,认为印支-燕山期先存逆冲断裂复活形成壳间拆离体系,并以简单剪切变形方式控制裂谷盆地发育,是其根本成盆机制;南、北部坳陷烃源岩主排烃期为三垛组二段沉积时期,自渐新世构造反转后热演化终止,古埋深和古地温场条件共同控制现今南、北部坳陷相同深度烃源岩热成熟度差异. 相似文献
20.
《Journal of Asian Earth Sciences》2011,40(6):608-619
The study area encompasses the Eastern Continental Margin of India (ECMI) and the adjoining deep water areas of Bay of Bengal. The region has evolved through multiple phases of tectonic activity and fed by abundant supply of sediments brought by prominent river systems of the Indian shield. Detailed analysis of total field magnetic and satellite-derived gravity data along with multi channel seismic reflection sections is carried out to decipher major tectonic features, basement structure, and the results have been interpreted in terms of basin configuration and play types for different deep water basins along the ECMI. Interpretation of various image enhanced gravity and magnetic anomaly maps suggest that in general, the ENE–WSW trending faults dominate the structural configuration at the margin. These maps also exhibit a clear density transition from the region of attenuated continental crust/proto oceanic crust to oceanic crust based on which the Continent Ocean Boundary (COB) has been demarcated along the margin. Basement depths estimated from magnetic data indicate that the values range from 1 to 12 km below sea level and deepen towards the Bengal Fan in the north and reveal horst–graben features related to rifting. A comparison of basement depths derived from seismic data indicates that in general, the basement trends and depths are comparable in Cauvery and Krishna–Godavari basins, whereas, in the Mahanadi basin, basement structure over the 85°E ridge is clearly revealed in seismic data. Further, eight multichannel seismic sections across different basins of the margin presented here reveal fault pattern, rift geometries and depositional trends related to canyon fills and channel–levee systems and provide a basic framework for future petroleum in this under explored frontier. 相似文献