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1.
南海北部陆缘地壳结构探测结果分析 总被引:29,自引:4,他引:29
深部地震和重力资料反演揭示了南海北部陆缘地壳结构在总体上由北部的华南沿海(厚约30km)向南部的洋盆(5──8km)逐渐减薄。南海的近SN向拉张不仅造成南北方向地壳结构的巨大变化,也造成东西向的明显变化。在南海北部陆缘的西部,局部拉张产生了一系列裂谷构造。西沙海槽作为一条狭窄的陆内裂谷向西延伸,海槽南北两侧地壳厚度超过25km,海槽中部地壳减薄至不足10km。西端的莺歌海盆地地壳厚仅5km,缺少明显的壳内反射-折射。在珠江口盆地中部,地壳厚度在下陆坡明显减薄,地壳下部存在较薄的(3──4km)高速层(地震波速7.2──7.5km·s-1);在珠江口盆地东部,地壳底部存在约 10km厚、300km宽的高速层。在台湾地区,由于弧陆碰撞,曾经减薄的陆壳在碰撞带增厚,莫霍面深度超过30km。南海北部陆缘在裂谷拉张和海底扩张期间岩浆活动平静,表明南海北部陆缘为非火山型陆缘。 相似文献
2.
南海的形成、演化与油气资源(英文) 总被引:9,自引:0,他引:9
何廉声 《海洋地质与第四纪地质》1988,(2)
一、南海是在欧亚板块上发生发展的.其区域板块主要是元古代(2300—1288Ma)以来多个时期形成的地壳块体构成.其基本格局:西北为印支、华南元古代一古生代陆壳微板块拼合区;中部是白垩纪—中新世洋壳或过渡壳扩张区;东及东南部是由垩纪以来过渡壳复杂聚敛区.它们先后经历了7个旋回的构造作用,形成了7个微板块区34个地块(带).二、南海的形成主要导源于中中生代开始的大洋板块作用下,欧业板块东南缘发生张裂和海底微扩张的结果.白垩纪(126—120Ma)南海第一次海底扩张,产生北东向M8-M17线状磁条的洋壳海盆以及海盆两侧北东向被动陆缘沉积盆地等造海构造系列和自垩纪—始新世西北婆罗州和菲律宾聚敛构造系列.渐新世—中新世(32一17Ma)第二次海底扩张在中央海盆出现近东西向5d一11线状磁条的洋壳,南海南、北两侧地壳减薄,异常地幔发生及被动陆缘沉积盆地等造海构造系列和迭加在婆罗州和菲律宾前期聚敛带上的聚敛构造系列等,均是这个时期产物.后期吕宋等菲律宾聚带发生逆时针旋动并向北迁移35°,使南海的洋壳从马尼拉海沟向东消减,从而导致南海边缘海的形成.三、南海两次海底扩张和相应的沉积作用,形成了各种类型沉积盆地,特别是南、北西陆缘区白垩纪—始新世、晚渐新世一中新世两套生储盖组合相迭置的陆缘含油 相似文献
3.
南海磁静区位于南海北部的洋陆结合带上,在磁异常图上位于陆架高值正磁异常带以南,海盆磁异常条带区以北。收集了南海北部的地质和地球物理相关资料,总结了南海北部磁静区的研究现状,对ΔT磁异常数据进行了低纬度化极处理,参考磁静区周围的自由空间重力异常分布,结合区域地质背景划分了南海磁静区的分布;采用小波多尺度分解方法讨论了南海北部磁静区及周围区域的重磁场特征,对主要界面的反演发现磁静区内存在磁性基底深度增加、居里等温面隆升、磁性层厚度减薄和莫霍面抬升的现象,认为南海磁静区形成的直接原因是区域内磁性层厚度的减薄,包括中生代末期地壳的拉张沉降使区域老地层断陷,磁性基底深度增加,磁异常减弱;拉张减薄促使深部地幔热物质向上运移,莫霍面抬升,磁性层发生热退磁,居里等温面抬升,磁性层厚度减薄,磁异常减弱;南海扩张期和张裂以后磁静区的热活动剧烈,深部高温物质底侵,形成高速层,进一步减弱了区域磁异常。 相似文献
4.
冲绳海槽地壳结构与性质研究进展和新认识 总被引:2,自引:0,他引:2
冲绳海槽是张裂于东亚大陆边缘的弧后盆地,对其地壳结构性质的研究具有重要的理论和现实意义。本文在总结冲绳海槽重力场、广角反射/折射地震探测、海底磁异常条带以及火山岩和岩浆作用这4个方面研究成果的基础上,对海槽的地壳结构、地壳性质和所处的构造演化阶段进行了探讨。认为冲绳海槽绝大部分地区地壳厚度大于正常洋壳,应属减薄的陆壳,由裂陷作用形成;但海槽中段和南段中央地堑地壳速度结构与洋壳类似,发育条带状磁异常,且已有大量幔源物质参与了地壳的组成,具备初始扩张作用的特征。对于海槽内是否存在洋壳,仍需进一步调查和研究。 相似文献
5.
南海北部潮汕坳陷海区海底地震仪调查实验 总被引:6,自引:2,他引:4
潮汕坳陷被认为是一个具有良好油气前景的中生代残留沉积坳陷,其中生代地层也被新近的钻井证实。为研究其盆地深部构造,“十五”863课题跨越该区进行了深地质调查。调查采用5台国产海底地震仪记录深部地震资料。处理结果显示本次调查清楚地记录到了来自地壳内部和Moho面的震相,这是国产海底地震仪在南海地区的首次成功实践。海底地震仪记录揭示沿测线的地壳在南海形成过程中减薄程度较低,中生代地层速度较高,代表致密的岩石,这些因素可能不利于油气的储集,需要在勘探中避开。 相似文献
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南海北部地球物理特征及地壳结构 总被引:8,自引:0,他引:8
为了研究南海地壳结构,中国和日本合作在南海北部首次进行了以炸药为震源的综合地球物理调查。经初步分析其地壳结构主要特征为:南海北部地壳分为沉积层、上地壳层、中地壳层及下地壳层。大陆架及上陆坡地壳厚度大、稳定。下陆坡地壳厚度除中地壳外,其他壳层厚度减薄且不稳定。深海盆地壳分3层,厚度虽薄但相对稳定,其底部缺失7.3km·s^-1的高速层。测区内地壳总厚度:陆壳26-30km,过渡壳13-22km,洋壳 相似文献
8.
南海东北部中生代海相地层的分布及其地质地球物理特征 总被引:1,自引:0,他引:1
南海东北部的珠江口盆地珠一坳陷、东沙隆起、潮汕坳陷和台西南盆地等4个地质构造单元中,除发育巨厚新生代地层外,还发育并保留较厚的早白垩世和早侏罗世海相地层.这些地层的地震反射特征表现为大角度倾斜、可连续追踪和中低频的反射层序.由叠加速度推算的层速度为4.3-5.0km·s-1.这些中生代地层具坳陷型沉积特征而与新生代断陷型充填式沉积明显不同,残存厚度约4 000-5 000m.东沙-澎湖-北港隆起带是中生代华南地块与南海地块的缝合拼接带.该拼接带显示为地壳增厚和高磁异常,古特提斯在此消亡. 相似文献
9.
南海东北部深部构造与中新生代沉积盆地 总被引:9,自引:1,他引:9
利用OBS资料作约束条件对南海东北部的地球物理资料,主要是重力资料和多道反射地震资料进行反演,获取比较理想的莫霍面深度,地壳厚度,中生代沉积基底面,新生代沉积底界面等地壳结构信息,研究发现该区中生代沉积盆地形成模式与新生代沉积盆地的形成模式不同,中生代沉积基底与莫霍面呈正相关,而新生代沉积基底则与莫霍面呈明显的镜像关系。中生仝层不受边界断层控制,中生代沉积基底与莫霍面呈正相关,而新生代沉积基底则与莫霍面呈明显的镜像关系。中生代地层不受边界断层控制。中生代沉积坳陷边界实质上是残留的中生代地层的边界,中生代沉积盆地具有大型坳陷沉积特征,而新生代盆地为断陷盆地。 相似文献
10.
对跨南海西南次海盆及两侧陆缘的一条1050km长的、包括海底地震(OBS)、长排列多道地震和重磁在内的综合地球物理探测剖面(CFT)进行了构造成像和研究。在多道地震成像基础上建立了CFT剖面初始速度模型, 进而通过初至波层析成像方法反演了CFT剖面的速度结构模型, 在重力异常资料的约束下建立了CFT剖面的综合地壳结构模型。讨论了沿CFT剖面出现的下地壳高速体、龙门海山的低密度物质等地质问题。结果表明, 下地壳高速层在北部陆坡、西南海盆和南部南沙地块均有分布, 厚度在0~4km之间, 可能与陆缘下地壳物质和地幔物质熔融混合, 以及深海盆海底扩张期间构造拉伸导致地幔蛇纹岩化有关。 相似文献
11.
Crustal Structures of the Northernmost South China Sea: Seismic Reflection and Gravity Modeling 总被引:2,自引:0,他引:2
The South China Sea (SCS) is a marginal sea off shore Southeast Asia. Based on magnetic study, oceanic crust has been suggested in the northernmost SCS. However, the crustal structure of the northernmost SCS was poorly known. To elaborate the crustal structures in the northernmost SCS and off southwest Taiwan, we have analyzed 20 multi-channel seismic profiles of the region. We have also performed gravity modeling to understand the Moho depth variation. The volcanic basement deepens southeastwards while the Moho depth shoals southeastwards. Except for the continental margin, the northernmost SCS can be divided into three tectonic regions: the disturbed and undisturbed oceanic crust (8–12 km thick) in the southwest, a trapped oceanic crust (8 km thick) between the Luzon-Ryukyu Transform Plate Boundary (LRTPB) and Formosa Canyon, and the area to the north of the Formosa Canyon which has the thickest sediments. Instead of faulting, the sediments across the LRTPB have only displayed differential subsidence offset of about 0.5–1 s in the northeast side, indicating that the LRTPB is no longer active. The gravity modeling has shown a relatively thin crust beneath the LRTPB, demonstrating the sheared zone character along the LRTPB. However, probably because of post-spreading volcanism, only the transtension-shearing phenomenon of volcanic basement in the northwest and southeast ends of the LRTPB can be observed. These two basement-fractured sites coincide with low gravity anomalies. Intensive erosion has prevailed over the whole channel of the Formosa Canyon. 相似文献
12.
南海东北部的断裂分布及其构造格局研究 总被引:3,自引:0,他引:3
通过对南海东北部重磁异常的分析和处理,结合珠江口盆地、潮汕坳陷等地区的综合地质地球物理研究成果,根据研究区的重磁异常特征划分了4个异常区。应用地球物理数据处理方法,推断了该区的主要断裂35条,其主要走向为NW、NE、NEE向及S-N向4组。综合各方面研究成果在该区划分了7个构造单元。依据地震剖面、物性资料和重磁资料的分析,对南海东北部地区中生界的地层标定、构造与结构特征有了新的认识,研究了该地区前第三系基底和中生界的分布,并对南海东北部构造演化进行了探讨。 相似文献
13.
Crustal features of the northeastern South China Sea: insights from seismic and magnetic interpretations 总被引:1,自引:0,他引:1
Yi-Ching Yeh Shu-Kun Hsu Wen-Bin Doo Jean-Claude Sibuet Char-Shine Liu Chao-Shing Lee 《Marine Geophysical Researches》2012,33(4):307-326
We interpret seven two-dimensional deep-penetration and long-offset multi-channel seismic profiles in the northernmost South China Sea area, which were collected by R/V Marcus G. Langseth during the TAIwan GEodynamics Research (TAIGER) project in 2009. To constrain the crustal characteristics, magnetic inversion and forward magnetic modeling were also performed. The seismic results clearly show tilted faulting blocks in the upper crust and most of the fault plane connects downward to a quasi-horizontal detachment as its bottom in the south of the Luzon-Ryukyu transform plate boundary. North of the plate boundary, a small-scale failed rifted basin (minimum 5 km in crustal thickness) with negative magnetization probably indicates an extended continental origin. Significant lower crustal material (LCM) was imaged under a crustal fracture area which indicated a continent and ocean transition origin. The thickest LCM (up to 6.5 km) is located at magnetic isochron C15 that is probably caused by the magma supply composite of a Miocene syn-rift volcanic event and Pliocene Dongsha volcanic activity for submarine volcanoes and sills in the surrounding area. The LCM also caused Miocene crustal blocks to be uplifted reversely as 17 km crustal thickness especially in the area of magnetic isochron C15 and C16. In addition, the wide fault blocks and LCM co-existed on the magnetic striped area (i.e. C15–C17) in the south of the Luzon-Ryukyu transform plate boundary. Magnetic forward modeling suggests that the whole thick crustal thickness (>12 km thick) needs to be magnetized in striped way as oceanic crust. However, the result also shows that the misfit between observed and synthetic magnetic anomaly is about 40 nT, north of isochron C16. The interval velocity derived from pre-stack time migration suggests that the crust is composed of basaltic intrusive upper crust and lower crustal material. The crustal nature should refer to a transition between continent and ocean. Thus, the magnetic reversals may be produced in two possible ways: basaltic magma injected along the crustal weak zone across magnetic reversal epoch and because some undiscovered ancient piece of oceanic crust existed. The crustal structure discrimination still needs to be confirmed by future studies. 相似文献
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15.
TAIGER project deep-penetration seismic reflection profiles acquired in the northeastern South China Sea (SCS) provide a detailed view of the crustal structure of a very wide rifted continental margin. These profiles document a failed rift zone proximal to the shelf, a zone of thicker crust 150 km from the shelf, and gradually thinning crust toward the COB, spanning a total distance of 250–300 km. Such an expanse of extended continental crust is not unique but it is uncommon for continental margins. We use the high-quality images from this data set to identify the styles of upper and lower crustal structure and how they have thinned in response to extension and, in turn, what rheological variations are predicted that allow for protracted crustal extension. Upper crustal thinning is greatest at the failed rift (βuc ≈ 7.5) but is limited farther seaward (βuc ≈ 1–2). We interpret that the lower crust has discordantly thinned from an original 15–17 km to possibly less than 2–3 km thick beneath the central thick crust zone and more distal areas. This extreme lower crustal thinning indicates that it acted as a weak layer allowing decoupling between the upper crust and the mantle lithosphere. The observed upper crustal thickness variations and implied rheology (lower crustal flow) are consistent with large-scale boudinage of continental crust during protracted extension. 相似文献
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Structures of the northeasternmost South China Sea continental margin and ocean basin: geophysical constraints and tectonic implications 总被引:2,自引:0,他引:2
Chun-Feng Li Zuyi Zhou Jiabiao Li Hujun Hao Jianhua Geng 《Marine Geophysical Researches》2007,28(1):59-79
The northeastern part of the South China Sea is a special region in many aspects of its tectonics. Both recent drilling into
the Mesozoic and new reflection seismic surveys in the area provide a huge amount of data, fostering new understanding of
the continental margin basins and regional tectonic evolution. At least four half-grabens are developed within the Northern
Depression of the Tainan Basin, and all are bounded on their southern edges by northwestward-dipping faults. One of the largest
half-grabens is located immediately to the north of the Central Uplift and shows episodic uplift from the late Oligocene to
late Miocene. Also during that period, the Central Uplift served in part as a material source to the Southern Depression of
the Tainan Basin. The Southern Depression of the Tainan Basin is a trough structure with deep basement (up to 9 km below sealevel
or 6 km beneath the sea bottom) and thick Cenozoic sedimentation (>6 km thick). Beneath the Southern Depression we identified
a strong landward dipping reflector within the crustal layer that represents a significant crustal fault. This reflector coincides
with a sharp boundary in crustal thicknesses and Moho depths. We show that the northeasternmost South China Sea basin, which
may have undergone unique evolution since the late Mesozoic, is markedly different from the central South China Sea basin
and the Huatung Basin, both geologically and geophysically. The Cenozoic evolution of the region was largely influenced by
pre-existing weaknesses due to tectonic inheritance and transition. The South China Sea experienced multiple stages of Cenozoic
extension. 相似文献
18.
南海北缘新生代盆地沉积与构造演化及地球动力学背景 总被引:32,自引:0,他引:32
南海北缘新生代沉积盆地是全面揭示南海北缘形成演化及与邻区大地构造单元相互作用的重要窗口。通过对盆地沉积-构造特征分析,南海北缘新生代裂陷过程显示出明显的多幕性和旋转性的特点。在从北向南逐渐迁移的趋势下,东、西段裂陷过程也具有一定的差异,西部裂陷活动及海侵时间明显早于东部,裂陷中心由西向东呈雁列式扩展。晚白垩世-早始新世裂陷活动应是东亚陆缘中生代构造-岩浆演化的延续,始新世中、晚期太平洋板块俯冲方向改变导致裂陷中心南移,印度欧亚板块碰撞效应是南海中央海盆扩张方向顺时针旋转的主要原因。 相似文献
19.
Ching-Hui Tsai Shu-Kun Hsu Yi-Ching Yeh Chao-Shing Lee Kanyuan Xia 《Marine Geophysical Researches》2004,25(1-2):63-78
Magnetic data suggest that the distribution of the oceanic crust in the northern South China Sea (SCS) may extend to about 21 °N and 118.5 °E. To examine the crustal features of the corresponding continent–ocean transition zone, we have studied the crustal structures of the northern continental margin of the SCS. We have also performed gravity modeling by using a simple four-layer crustal model to understand the geometry of the Moho surface and the crustal thicknesses beneath this transition zone. In general, we can distinguish the crustal structures of the study area into the continental crust, the thinned continental crust, and the oceanic crust. However, some volcanic intrusions or extrusions exist. Our results indicate the existence of oceanic crust in the northernmost SCS as observed by magnetic data. Accordingly, we have moved the continent–ocean boundary (COB) in the northeastern SCS from about 19 °N and 119.5 °E to 21 °N and 118.5 °E. Morphologically, the new COB is located along the base of the continental slope. The southeastward thinning of the continental crust in the study area is prominent. The average value of crustal thinning factor of the thinned continental crust zone is about 1.3–1.5. In the study region, the Moho depths generally vary from ca. 28 km to ca. 12 km and the crustal thicknesses vary from ca. 24 km to ca. 6 km; a regional maximum exists around the Dongsha Island. Our gravity modeling has shown that the oceanic crust in the northern SCS is slightly thicker than normal oceanic crust. This situation could be ascribed to the post-spreading volcanism or underplating in this region. 相似文献
20.
New Bathymetry and Magnetic Lineations Identifications in the Northernmost South China Sea and their Tectonic Implications 总被引:12,自引:1,他引:12
Shu-Kun Hsu Yi-ching Yeh Wen-Bin Doo Ching-Hui Tsai 《Marine Geophysical Researches》2004,25(1-2):29-44
The seafloor spreading of the South China Sea (SCS) was previously believed to take place between ca. 32 and 15 Ma (magnetic anomaly C11 to C5c). New magnetic data acquired in the northernmost SCS however suggests the existence of E–W trending magnetic polarity reversal patterns. Magnetic modeling demonstrates that the oldest SCS oceanic crust could be Late Eocene (as old as 37 Ma, magnetic anomaly C17), with a half-spreading rate of 44 mm/yr. The new identified continent–ocean boundary (COB) in the northern SCS generally follows the base of the continental slope. The COB is also marked by the presence of a relatively low magnetization zone, corresponding to the thinned portion of the continental crust. We suggest that the northern extension of the SCS oceanic crust is terminated by an inactive NW–SE trending trench-trench transform fault, called the Luzon–Ryukyu Transform Plate Boundary (LRTPB). The LRTPB is suggested to be a left-lateral transform fault connecting the former southeast-dipping Manila Trench in the south and the northwest-dipping Ryukyu Trench in the north. The existence of the LRTPB is demonstrated by the different patterns of the magnetic anomalies as well as the different seafloor morphology and basement relief on both sides of the LRTPB. Particularly, the northwestern portion of the LRTPB is marked by a steep northeast-dipping escarpment, along which the Formosa Canyon has developed. The LRTPB probably became inactive at ca. 20 Ma while the former Manila Trench prolonged northeastwards and connected to the former Ryukyu Trench by another transform fault. This reorganization of the plate boundaries might cause the southwestern portion of the former Ryukyu Trench to become extinct and a piece of the Philippine Sea Plate was therefore trapped amongst the LRTPB, the Manila Trench and the continental margin. 相似文献