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通过对毕鸟夫带滑动向量的研究表明,印度一澳大利亚和东南亚板块之间发生着接近N-S向的汇聚运动。因此,沿着苏门答腊的俯冲运动是斜向的,而在爪哇岛西南部则几乎是垂向的俯冲运动(图1)。苏门答腊下方的斜向俯冲运动导致了汇聚运动的分离,走滑分量沿着苏门答腊主走滑断裂和明打威断裂被吸收。基于地震证据和对俯冲运动有关的深层地震的研究表明,在苏门答腊南部和巽他海峡下面,俯冲板块内部呈不连续状态。有研究者认为两个俯冲带之间的转换带发生在爪哇西南部。 相似文献
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Résumé L'étude de plusieurs profils de sismique réflexion, magnétisme et gravimétrie a permis de dégager les grands traits de la structure de la marge continentale à l'ouest du Spitzberg. Cette marge est représentée au niveau du talus continental par un bassin sédimentaire dont la largeur se réduit en allant vers le Nord. Ce bassin est limité à l'Ouest par les premiers contreforts de la dorsale d'Atka qui a joué un rôle de barrage pour les apports sédimentaires. Les données de la sismique réflexion et du magnétisme indiquent que la vallée d'Atka est sans doute une zone actuelle d'expansion. Ces résultats sont en bon accord avec le modèle récent d'ouverture de la mer de Norvège. De plus, la dorsale d'Atka semble avoir subi au pliocène un réajustement ayant modifié les processus sédimentaires au niveau de la marge.
Contribution No. 258 du Department Scientifique du Centre Océanologique de Bretagne. 相似文献
The main structural features of the continental margin off West Spitzberg are outlined. Seaward the Atka ridge has acted like a dam for the eastward-flowing sediments and thus helped to build up a large sedimentary basin, narrowing towards the North. Magnetic and seismic data show that the Atka Valley is probably an active accretion rift valley. These results are in good agreement with the last hypothesis on the opening of the Norwegian Sea. During the Pliocene, a tectonic event may have affected Atka ridge and modified the subsequent sedimentation.
Contribution No. 258 du Department Scientifique du Centre Océanologique de Bretagne. 相似文献
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Late Cenozoic geodynamic evolution of eastern Indonesia 总被引:2,自引:0,他引:2
Florent Hinschberger Jacques-Andr Malod Jean-Pierre Rhault Michel Villeneuve Jean-Yves Royer Safri Burhanuddin 《Tectonophysics》2005,404(1-2):91-118
This paper presents an internally and globally consistent model of plate evolution in eastern Indonesia from Middle Miocene to Present time. It is centered on the Banda Sea region located in the triple junction area between the Pacific–Philippine, Australia and South–East Asia plates. The geological and geophysical data available from Indonesia were until recently insufficient to define a unique plate tectonic model. In this paper, the new data taken into account clearly restrict the possible interpretations. Owing to a great number of geological, geophysical and geochemical studies, the major plate boundaries (the Sunda–Banda subduction zone to the south, the Tarera–Aiduna Fault zone and the Seram Thrust to the east, and the Sorong Fault zone and Molucca Sea collision zone to the north) are now clearly identified. The age of the major tectonic structures is also better known. Geodetic measurements well constrain the Present time plate kinematics. We also consider the deformation history within eastern Indonesia, where numerous short-lived microplates and their related microcontinents successively accreted to the Asiatic margin. Moreover, magnetic anomalies identification of the North and South Banda Sea basins allows a precise kinematic reconstruction of the back-arc opening. We used the Plates software to test the coherency of our model, presented as a series of 4 plate reconstruction maps from 13 Ma to the present. Finally, the origin of oceanic domains restored by our reconstruction is discussed. 相似文献
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M. Villeneuve J. -J. Cornee R. Martini L. Zaninetti J. -P. Rehault S. Burhanudin J. Malod 《Geo-Marine Letters》1994,14(1):29-35
Ten rock samples were dredged during the Banda Sea I cruise in the northern slope of the Sinta Ridge, which separates the North and South Banda basins. Some of the samples are limestones from a very shallow marine environment, with Upper Norian (to Rhaetian?) benthic Foraminifera. Similarities with eastern Sulawesi, Buru and Seram are consistent with an independant Upper Triassic block and the origin of the Banda Sea microcontinents is questionable. 相似文献
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The Barents Sea is underlain by a thick (up to 5 km) sedimentary basin. Seismic refraction has outlined four main velocity discontinuities which have been correlated with geological units on the basis of the geological history of the region. The basin is underlain by a crystalline basement, the nature of which cannot be determined on the basis of seismic velocity alone. Metamorphosed Paleozoic units (velocities around 5–4 km/sec) lie over this basement. Their thickness is not well established but appears to reach 1 or 2 km in some cases. A very distinct and thick (up to 2.5 km) layer (4.1 km/sec) is found almost everywhere and is thought to correspond to a major discontinuity at the end ot the Paleozoic. This discontinuity is followed by a variable velocity layer (2.4–4 km/sec, up to 1.2 km thick) which includes Mesozoic and Cenozoic sediments and is limited to the south of the Barents Sea. The absence of thick Tertiary deposits support the idea that the Barents shelf was emergent at that time. Recent low-velocity sediments are found close to the shelf edge.Gravity anomaly trends reflect a series of depressions of the 5.4-km/sec layer isobath map and suggest that the deeper part of the basin is made of a succession of faulted blocks or intense folds. 相似文献
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Yolande Razafindrazaka Thogne Randriamananjara Alain Piqu Catherine Thouin Edgard Laville Jacques Malod Jean-Pierre Rhault 《Journal of African Earth Sciences》1999,28(4):949-959
The Majunga Basin is located in the northwestern part of Madagascar with a N45–60°E trending axis. It was filled by almost exclusively continental Karoo Supergroup sediments, which are Permian to Early Jurassic in age, and by younger sequences, mainly marine, that were deposited from the Middle Jurassic to the present.The Karoo Basin geometry is deduced from the analysis of seismic sections. A central northeast trending horst is flanked by two sub-basins. Deposition of the Karoo sequences was controlled by these northeast trending faults. On the contrary, the Middle Jurassic to present sequences witness only a slight tilting of the basement towards the northwest.The development of the Majunga Basin includes, therefore, two successive stages. In the synrift episode, from Permian to Early Jurassic times, the sedimentation was syntectonic, controlled by synsedimentary faulting and the creation of a horst and graben extensive pattern. The postrift episode started during the Middle Jurassic.These two stages of the Majunga Basin development correspond to the geodynamic evolution recorded elsewhere in this part of the Gondwana. 相似文献
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