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1.
新的地层和古生物学研究结果表明,措勤盆地在晚古生代一早中生代不存在长达75Ma以上的沉积间断.其中,晚二叠世-晚三叠世诺利期都是海相碳酸盐岩地层,晚三叠世瑞替期-早中侏罗世为陆缘碎屑岩地层.两者之间为角度不整合接触.措勤盆地在晚二叠世-晚三叠世诺利期一直处于海相碳酸盐岩盆地中.晚三叠世瑞替期-早中侏罗世仍然是接受巨厚沉积的低洼地区。从宏观的油气勘探的战略评价角度看.措勤盆地在中二叠世栖霞期-晚三叠世诺利期的海相碳酸盐岩地层具有生油层的性质,上三叠统瑞替阶-中下侏罗统具有盖层的性质,两者之间的角度不整合具有储集层的性质。措勤盆地中二叠统-下侏罗统构成一个油气的有利勘探层系.称为古格层系。  相似文献   

2.
新的地层和古生物学研究结果表明,措勤盆地在晚古生代一早中生代不存在长达75Ma以上的沉积间断.其中,晚二叠世-晚三叠世诺利期都是海相碳酸盐岩地层,晚三叠世瑞替期-早中侏罗世为陆缘碎屑岩地层.两者之间为角度不整合接触.措勤盆地在晚二叠世-晚三叠世诺利期一直处于海相碳酸盐岩盆地中.晚三叠世瑞替期-早中侏罗世仍然是接受巨厚沉积的低洼地区。从宏观的油气勘探的战略评价角度看.措勤盆地在中二叠世栖霞期-晚三叠世诺利期的海相碳酸盐岩地层具有生油层的性质,上三叠统瑞替阶-中下侏罗统具有盖层的性质,两者之间的角度不整合具有储集层的性质。措勤盆地中二叠统-下侏罗统构成一个油气的有利勘探层系.称为古格层系。  相似文献   

3.
The comprehensive study of the tectonics-sequence stratigraphic-petroleum system shows that five sets of major regional and some local source rocks were developed in the tectonic evolution of South China, including the Lower Cambrian and Lower Silurian in the Caledonian cycle, the Middle Permian and Upper Permian in the Hercynian cycle, and the Lower Triassic in the Indo-Sinian cycle. Due to the inhomogeneous maturity of source rocks in this area, gas exploration would mainly be carried out in the Lower Paleozoic areas, while oil and gas exploration would be in the Upper Paleozoic ones. The reformation from the Indo-Sinian cycle to the Himalayan cycle exerted decisive influence on the hydrocarbon accumulation in the Mesozoic-Cenozoic basin and marine sequences in southern China. The petroleum systems formed in the medium-late period of the superimposed basins are of the greatest potential. The distribution of primary and secondary oil-gas pools was mainly affected by favorable sedimentary facies, ancient uplift and slope. The comprehensive evaluation concluded that the focuses for petroleum exploration in the marine sequences of southern China will be in the superimposed basins along the margin of Yangtze landmass, the Subei-southern South Yellow Sea basin and the marine sequences preserved under the over-thrust nappe along the northern margin of the Jiangnan uplift. __________ Translated from Acta Petrolei Sinica, 2007, 28(3): 1–7 [译自:石油学报]  相似文献   

4.
巴颜喀拉残留洋盆的沉积特征   总被引:6,自引:4,他引:6  
巴颜喀拉盆地垂向沉积序列表明:盆地于早古生代被动陆缘的浅海基础上裂陷、拉开,泥盆纪贯通,早石炭世洋盆扩展为成熟大洋,晚石炭世洋盆北部开始消减、南部继续扩张,晚二叠世-中三叠世进入残留洋阶段,晚三叠世转化为周缘前陆盆地.三叠纪末完全闭合,盆地自形成到消亡为一个连续的沉积和地质构造演化过程。其主体由早中三叠世深海沉积、典型浊积岩复理石和晚三叠世浅海复理石、风暴岩沉积、海相磨拉石构成,北部零星出露了中二叠世海山型沉积,昆南结合带以北有早中三叠世岛弧沉积。以盆地为中心具有向南北两侧陆块双向相背俯冲的极性特点,东西两端的碰撞造山不迟于晚二叠世。总体反映了古特提斯晚二叠世-中三叠世的残留洋盆性质和主洋域之所在。  相似文献   

5.
Integrated biostratigraphic studies are undertaken on the newly discovered Gondwana successions of Purnea Basin which have been recognized in the subsurface below the Neogene Siwalik sediments. The four exploratory wells, so far drilled in Purnea Basin, indicated the presence of thick Gondwana sussession (± 2450m) with varied lithological features. However, precise age of different Gondwanic lithounits of this basin and their correlation with standard Gondwana lithounits is poorly understood due to inadequate biostratigraphic data.Present biostratigraphic studies on the Gondwana successions in the exploratory wells of PRN-A, RSG-A, LHL-A and KRD-A enable recognition of fifteen Gondwanic palynological zones ranging in age from Early Permian (Asselian-Sakmarian) to Late Triassic (Carnian-Norian). Precise age for the Gondwanic palynological zones, recognized in the Purnea Basin and already established in other Indian Gondwana basins, are provided in the milieu of additional palynological data obtained from the Gondwana successions of this basin.The Lower Gondwana (Permian) palynofloras of Purnea Basin recorded from the Karandighi, Salmari, Katihar and Dinajpur formations resemble the palynological assemblages earlier recorded from the Talchir, Karharbari, Barakar and Raniganj formations respectively, and suggests the full development of lower Gondwana succession in this basin. The Upper Gondwana (Triassic) succession of this basin is marked by the Early and Middle to Late Triassic palynofloras that resemble Panchet and Supra-Panchet (Dubrajpur/Maleri Formation) palynological assemblages, and indicates the occurrence of complete Upper Gondwana succession also in the Purnea Basin.The lithological and biostratigraphic attributes of Gondwana sediments from Purnea, Rajmahal and western parts of Bengal Basin (Galsi Basin) are almost similar and provides strong evidences about the existence of a distinct N-S trending Gondwana Graben, referred as the Purnea-Rajmahal-Galsi Gondwana Graben. Newly acquired biostratigraphic data from the Gondwana sediments of CHK-A, MNG-A and PLS-A wells from central part of Bengal Basin and Bouguer anomaly data suggest that these wells fall in a separate NE-SW trending graben of “Chandkuri-Palasi-Bogra Gondwana Graben”. Although, the post-Gondwana latest Jurassic-Early Cretaceous Rajmahal Traps and and intertrappean beds succeed the Upper Gondwana successions in Rajmahal, Galsi and Chandkuri-Palasi Gondwana basins, but not recorded in the drilled wells of Purnea Basin, instead succeeded by the Neogene Siwalik sediments.  相似文献   

6.
The Albertine Graben in western Uganda is a Mesozoic-Cenozoic rift basin with petroleum exploration potential. A fundamental evaluation of petroleum potential of the graben is given based on field research, data processing of gravity and magnetism, analysis of graben structure, geochemistry, reservoir and composition research. The basin has a double-layered framework and a large thickness of sediments. Gravity highs shown in a residual anomaly map might indicate central uplift zones. There exist at least two sets of mature or low-maturity source rocks corresponding to a certain source rock in the Cretaceous or Paleogene and Neogene strata. The graben has basement rock with potential reservoirs and Tertiary sandstone reservoirs and thus has petroleum exploration potential.  相似文献   

7.
内蒙古隆起晚古生代构造隆升的沉积记录   总被引:3,自引:0,他引:3  
马收先  孟庆任  武国利  段亮 《地质学报》2014,88(10):1771-1789
内蒙古隆起位于华北克拉通与兴蒙造山带的过渡部位,受古亚洲洋俯冲、闭合过程的影响,在晚古生代发生了重要的构造隆升。华北盆地北缘紧靠内蒙古隆起,其晚古生代沉积记录了内蒙古隆起的构造活动历史。本文对盆地冀北—辽西地区的晚石炭—中三叠世地层进行详细的沉积体系分析和物源研究,结果表明:1盆地由远滨—滨岸、扇三角洲、三角洲、河流四种沉积体系充填而成,总体上经历了由海陆交互到陆相的进积充填过程。在晚石炭—早二叠世,盆地边缘发育扇三角洲和河流体系,盆地内部由远滨—滨岸、三角洲与河流体系组成。在中二叠—中三叠世期间盆地整体发育河流体系。盆地的沉积中心位于唐山、宝坻一带;2古水流数据、碎屑锆石U-Pb年龄和Hf同位素表明盆地物源来自内蒙古隆起,源岩由中上元古界碎屑岩和碳酸盐岩、寒武—奥陶系碳酸盐岩、晚古生代岩浆岩以及少量前寒武结晶基底组成。大量沉积岩碎屑颗粒表明内蒙古隆起在晚古生代被沉积盖层所覆盖,在二叠纪末期花岗岩以及片麻岩砾石的出现代表了内蒙古隆起隆升和侵蚀作用的加强;3根据沉积体系和物源变化将盆地划分为三个充填序列,这些序列记录了内蒙古隆起的隆升和侵蚀过程。晚石炭—早二叠世充填序列以沉积岩砾石、泥盆纪碎屑锆石和凝灰岩夹层为特征,物源来自沉积盖层和晚古生代火山岩。该序列记录了内蒙古隆起陆缘弧的初始隆升和同期火山活动。中晚二叠世充填序列以河流环境下的火山碎屑岩和火山岩为主要特征,记录了华北北缘与南蒙地块的碰撞过程,碰撞导致内蒙古隆起的隆升,同时伴随火山喷发。早中三叠世充填序列以辫状河粗碎屑和花岗质砾石为特征,记录了古亚洲洋闭合后的伸展环境。  相似文献   

8.
Gravity signals from the lithosphere in the Central European Basin System   总被引:1,自引:0,他引:1  
We study the gravity signals from different depth levels in the lithosphere of the Central European Basin System (CEBS). The major elements of the CEBS are the Northern and Southern Permian Basins which include the Norwegian–Danish Basin (NDB), the North-German Basin (NGB) and the Polish Trough (PT). An up to 10 km thick sedimentary cover of Mesozoic–Cenozoic sediments, hides the gravity signal from below the basin and masks the heterogeneous structure of the consolidated crust, which is assumed to be composed of domains that were accreted during the Paleozoic amalgamation of Europe. We performed a three-dimensional (3D) gravity backstripping to investigate the structure of the lithosphere below the CEBS.Residual anomalies are derived by removing the effect of sediments down to the base of Permian from the observed field. In order to correct for the influence of large salt structures, lateral density variations are incorporated. These sediment-free anomalies are interpreted to reflect Moho relief and density heterogeneities in the crystalline crust and uppermost mantle. The gravity effect of the Moho relief compensates to a large extent the effect of the sediments in the CEBS and in the North Sea. Removal of the effects of large-scale crustal inhomogeneities shows a clear expression of the Variscan arc system at the southern part of the study area and the old crust of Baltica further north–east. The remaining residual anomalies (after stripping off the effects of sediments, Moho topography and large-scale crustal heterogeneities) reveal long wavelength anomalies, which are caused mainly by density variations in the upper mantle, though gravity influence from the lower crust cannot be ruled out. They indicate that the three main subbasins of the CEBS originated on different lithospheric domains. The PT originated on a thick, strong and dense lithosphere of the Baltica type. The NDB was formed on a weakened Baltica low-density lithosphere formed during the Sveco-Norwegian orogeny. The major part of the NGB is characterized by high-density lithosphere, which includes a high-velocity lower crust (relict of Baltica passive margin) overthrusted by the Avalonian terrane. The short wavelength pattern of the final residuals shows several north–west trending gravity highs between the Tornquist Zone and the Elbe Fault System. The NDB is separated by a gravity low at the Ringkøbing–Fyn high from a chain of positive anomalies in the NGB and the PT. In the NGB these anomalies correspond to the Prignitz (Rheinsberg anomaly), the Glueckstadt and Horn Graben, and they continue further west into the Central Graben, to join with the gravity high of the Central North Sea.  相似文献   

9.
The Central European Basin System (CEBS) is composed of a series of subbasins, the largest of which are (1) the Norwegian–Danish Basin (2), the North German Basin extending westward into the southern North Sea and (3) the Polish Basin. A 3D structural model of the CEBS is presented, which integrates the thickness of the crust below the Permian and five layers representing the Permian–Cenozoic sediments. Structural interpretations derived from the 3D model and from backstripping are discussed with respect to published seismic data. The analysis of structural relationships across the CEBS suggests that basin evolution was controlled to a large degree by the presence of major zones of crustal weakness. The NW–SE-striking Tornquist Zone, the Ringkøbing-Fyn High (RFH) and the Elbe Fault System (EFS) provided the borders for the large Permo–Mesozoic basins, which developed along axes parallel to these fault systems. The Tornquist Zone, as the most prominent of these zones, limited the area affected by Permian–Cenozoic subsidence to the north. Movements along the Tornquist Zone, the margins of the Ringkøbing-Fyn High and the Elbe Fault System could have influenced basin initiation. Thermal destabilization of the crust between the major NW–SE-striking fault systems, however, was a second factor controlling the initiation and subsidence in the Permo–Mesozoic basins. In the Triassic, a change of the regional stress field caused the formation of large grabens (Central Graben, Horn Graben, Glückstadt Graben) perpendicular to the Tornquist Zone, the Ringkøbing-Fyn High and the Elbe Fault System. The resulting subsidence pattern can be explained by a superposition of declining thermal subsidence and regional extension. This led to a dissection of the Ringkøbing-Fyn High, resulting in offsets of the older NW–SE elements by the younger N–S elements. In the Late Cretaceous, the NW–SE elements were reactivated during compression, the direction of which was such that it did not favour inversion of N–S elements. A distinct change in subsidence controlling factors led to a shift of the main depocentre to the central North Sea in the Cenozoic. In this last phase, N–S-striking structures in the North Sea and NW–SE-striking structures in The Netherlands are reactivated as subsidence areas which are in line with the direction of present maximum compression. The Moho topography below the CEBS varies over a wide range. Below the N–S-trending Cenozoic depocentre in the North Sea, the crust is only 20 km thick compared to about 30 km below the largest part of the CEBS. The crust is up to 40 km thick below the Ringkøbing-Fyn High and up to 45 km along the Teisseyre–Tornquist Zone. Crustal thickness gradients are present across the Tornquist Zone and across the borders of the Ringkøbing-Fyn High but not across the Elbe Fault System. The N–S-striking structural elements are generally underlain by a thinner crust than the other parts of the CEBS.The main fault systems in the Permian to Cenozoic sediment fill of the CEBS are located above zones in the deeper crust across which a change in geophysical properties as P-wave velocities or gravimetric response is observed. This indicates that these structures served as templates in the crustal memory and that the prerift configuration of the continental crust is a major controlling factor for the subsequent basin evolution.  相似文献   

10.
In the Late Paleozoic, the Sino-Korean (North China) and Yangtze-Cathaysian (South China) cratons collided. The Carboniferous and Permian foreland basin to the north of the Tongbo-Dabie Mountains, and elongate intermontane basins in East Qinling, were filled by marine to terrestrial sediments, in which the fauna and flora communicated from North China, South China, and West China. In Triassic time, the Dabie-Sulu Mountains became a Himalaya-type mountain range as a result of continent-continent collision and doubling of the crust. Marked exhumation of this mountain range shed huge amounts of detritus to the west. First filled were the remnant ocean basins in Qinling. As the remnant basins filled, submarine fan deposition shifted to the west to gradually fill the Songpan-Ganzi area. Songpan-Ganzi is surrounded by continents with pre-Sinian basement. The Sinian and Paleozoic strata and their fauna and flora are of Yangtzean affinity.

Beginning in the Permian, a midocean-ridge triple junction was developed in Songpan-Ganzi, and the new oceanic crust provided more space for submarine fans. Later, a Triassic subduction zone was developed along the western margin of Songpan-Ganzi, and the rising island arc provided a smaller amount of detritus to its backarc basin in the east, which became part of Songpan-Ganzi. During the Early and Middle Triassic, the Dabie-Sulu high mountain ranges blocked the monsoon from blowing to the north, and, therefore, typical redbeds were deposited in North China for at least 15 million years, whereas the deposits of the same age in South China are still shallow-marine and littoral facies with coal measures. In the Late Triassic and Jurassic, the Dabie-Sulu mountain range was leveled to low hilly country. The monsoon blew to the north very easily, and coal measures were deposited all over North China. In Songpan-Ganzi, the Triassic submarine fan deposits were folded and metamorphosed during latest Triassic time, and the Songpan-Ganzi fold belt was formed. The Cenozoic Himalaya and its relationship with submarine fans in the Indian Ocean is similar to the Triassic Dabie-Sulu mountain range and its relationship with the Songpan-Ganzi submarine fans. Huge submarine fans and ultrahigh-pressure metamorphism are consequences of continent-continent collision, but the involved continents should have considerable sizes.  相似文献   

11.
A comparison of ore-lead isotope ratios of Pb-Zn deposits hosted in Triassic carbonates of the Eastern and Southern Alps with the isotopic composition of trace leads of their host rocks, of Triassic volcanics, and of the underlying clastic sediments shows that these rocks could have supplied only part of the ore lead. The isotopic signature of feldspar lead from crystalline basement rocks, however, reveals that they must have contributed a significant amount of metal to these deposits. The presence of barite and of thallium is also indicative that feldspars were the main source of lead. Arsenic is one of the few important trace elements in these deposits and is known to occur in some areas of Lower Paleozoic metasediments in unusually high concentrations. Any model explaining the origin of these deposits must consider the extensive leaching of the basement and to some extent of the overlying clastic sediments as well. How the metal-bearing solutions entered the lagoonal back-reef areas is still open to question as feeder channels have not yet been positively identified. The results further demonstrate that the basement also acted as a metal source for galena-bearing deposits hosted in Permian sediments, vein-type deposits in Permian volcanics, and probably the barite-fluorite polymetallic deposits along a Devonian erosional surface in the Carnic Alps as well.  相似文献   

12.
准噶尔盆地结构的石油物探综合解析   总被引:2,自引:1,他引:2  
准噶尔盆地经过50年石油物探工作,取得了丰富资料,对盆地地质结构的认识有了突破性进展.资料显示,二叠系与上下地层之间,存在一个比较明显的密度分界面,对认识和分析盆地重力场特征和异常极有帮助.各时代地层的磁性差异显示,二叠纪及中新生代沉积岩属弱(非)磁性(18×10-6~85×10-6 CGSM),内部磁性差异只能引起小幅度的微弱异常.石炭纪及其以前时代的变质岩、火成岩的磁化率都很大,平均在数百个单位以上,特别是火成岩的磁化率可达数几千至数万单位.这些具有磁性的火成岩,在准噶尔盆地均产生明显局部异常,20世纪70年代以前,石油工作者认为是盆地的磁性基底.与此同时,盆地周围大规模的区域地质调查证实,周边广泛分布的主要是上古生界地槽型沉积建造,而且多是火山碎屑岩沉积,下古生界很少,未发现可靠的前寒武纪露头.地震解释技术从二维到三维、从区块三维到区带三维,不仅从宏观上认识了盆地基底结构、沉积盖层等盆地地质结构,而且能从微观上认识圈闭、储层,在含油气有利构造的发现及石油勘探方面发挥了巨大的作用.  相似文献   

13.
《China Geology》2019,2(1):67-84
The South Yellow Sea Basin is a large sedimentary basin superimposed by the Mesozoic-Paleozoic marine sedimentary basin and the Mesozoic-Cenozoic terrestrial sedimentary basin, where no oil and gas fields have been discovered after exploration for 58 years. After the failure of oil and gas exploration in terrestrial basins, the exploration target of the South Yellow Sea Basin turned to the marine Mesozoic-Paleozoic strata. After more than ten years’ investigation and research, a lot of achievements have been obtained. The latest exploration obtained effective seismic reflection data of deep marine facies by the application of seismic exploration technology characterized by high coverage, abundant low-frequency components and strong energy source for the deep South Yellow Sea Basin. In addition, some wells drilled the Middle-Upper Paleozoic strata, with obvious oil and gas shows discovered in some horizons. The recent petroleum geological research on the South Yellow Sea Basin shows that the structure zoning of the marine residual basin has been redetermined, the basin structure has been defined, and 3 seismic reflection marker layers are traceable and correlatable in the residual thick Middle-Paleozoic strata below the continental Meso-Cenozoic strata in the South Yellow Sea Basin. Based on these, the seismic sequence of the marine sedimentary strata was established. According to the avaliable oil and gas exploration and research, the marine Mesozoic-Paleozoic oil and gas prospects of the South Yellow Sea were predicted as follows. (1) The South Yellow Sea Basin has the same sedimentary formation and evolution history during the sedimentary period of the Middle-Paleozoic marine basin with the Sichuan Basin. (2) There are 3 regional high-quality source rocks. (3) The carbonate and clastic reservoirs are developed in the Mesozoic-Paleozoic strata. (4) The three source-reservoir-cap assemblages are relatively intact. (5) The Laoshan Uplift is a prospect area for the Lower Paleozoic oil and gas, and the Wunansha Uplift is one for the marine Upper Paleozoic oil and gas. (6) The Gaoshi stable zone in the Laoshan Uplift is a favorable zone. (7) The marine Mesozoic-Paleozoic strata in the South Yellow Sea Basin has the geological conditions required to form large oil and gas fields, with remarkable oil and gas resources prospect. An urgent problem to be addressed now within the South Yellow Sea Basin is to drill parametric wells for the Lower Paleozoic strata as the target, to establish the complete stratigraphic sequence since the Paleozoic period, to obtain resource evaluation parameters, and to realize the strategic discovery and achieve breakthrough in oil and gas exploration understanding.©2019 China Geology Editorial Office.  相似文献   

14.
广西十万大山前陆冲断推覆构造   总被引:8,自引:0,他引:8  
通过十万大山盆地内地震剖面资料和TM遥感图象的地质构造解译,结合重力资料和野外地质观察及构造分析,阐述了十万大山前陆冲断推覆构造的发育特征和前陆盆地的构造演化。前陆冲断推覆构造由3个不同的构造变形带组成:卷入海西和印支期花岗岩体的逆冲断裂带、充填中生代陆相沉积并发生构造滑脱的前陆盆地和对应于华南准地台的前陆腹地。冲断推覆构造的形成和演化是与中、晚古生代钦州海槽晚二叠世的褶皱回返和中生代相继的构造复活密切联系的,它经历了3期主要构造应力作用事件:晚二叠世海西运动晚幕为冲断推覆构造的雏形期,晚三叠世印支运动晚幕的近SN向挤压是陆相前陆盆地的发育期;早白垩世末期燕山运动主幕NW—SE向挤压是现今十万大山前陆冲断推覆构造的成型期。  相似文献   

15.
At the base of the sedimentary section of the Timan-Pechora basin are Late Precambrian rifts, which are filled by unmetamorphosed sedimentary rocks 10 km and more than 10 km thick. The upper parts of these rift deposits have potential for gas. Structurally the Phanerozoic sedimen tary fill of the basin is mildly deformed in the west and central parts into several broad depressions and more narrow intervening highs. The eastern part is strongly deformed by overthrusts that were emplaced in the Late Paleozoic in connection with development of the Ural fold belt. Eight oil-gas plays are recognized in the basin: 1—Ordovician-Lower Devonian, 2—Middle Devonian-lower Frasnian, 3—upper Frasnian-Tournaisian, 4—Lower Carboniferous, 5—upper Visean-Lower Permian, 6—Lower Permian, 7—Upper Permian, and 8—Triassic. The promising oil-gas basin is of great interest for global stratigraphy and tectonics as well as for petroleum exploration.  相似文献   

16.
Exploration Potential of Marine Source Rocks Oil-Gas Reservoirs in China   总被引:1,自引:0,他引:1  
So far,more than 150 marine oil-gas fields have been found onshore and offshore about 350. The marine source rocks are mainly Paleozoic and Mesozoic onshore whereas Tertiary offshore.Three genetic categories of oil-gas reservoirs have been defined for the marine reservoirs in China:primary reservoirs,secondary reservoirs and hydrocarbon-regeneration reservoirs.And three exploration prospects have also been suggested:(1)Primary reservoirs prospects,which are chiefly distributed in many Tertiary basins of the South China Sea(SCS),the Tertiary shelf basins of the East China Sea (ECS)and the Paleozoic of Tarim basin,Sichuan basin and Ordos basin.To explore large-middle-scale even giant oil-gas fields should chiefly be considered in this category reservoirs.These basins are the most hopeful areas to explore marine oil-gas fields in China,among which especially many Tertiary basins of the SCS should be strengthened to explore.(2)Secondary reservoirs prospects,which are mainly distributed in the Paleozoic and Mesozoic of the Tarim basin,Sichuan basin,Qiangtang basin and Chuxiong basin in western China,of which exploration potential is less than that of the primary reservoirs.(3)Hydrocarbon-regeneration reservoirs prospects,which are chiefly distributed in the Bohai Bay basin,North Jiangsu-South Yellow Sea basin,southern North China basin,Jianghan basin, South Poyang basin in eastern China and the Tarim basin in western China,of which source rocks are generally the Paleozoic.And the reservoirs formed by late-stage(always Cenozoic)secondary hydrocarbon generation of the Paleozoic source rocks should mainly be considered to explore,among which middle-small and small oil-gas fields are the chief exploration targets.As a result of higher thermal evolution of Paleozoic and Mesozoic source rocks,the marine reservoirs onshore are mainly gas fields,and so far marine oil fields have only been found in the Tarim basin.No other than establishing corresponding marine oil-gas exploration and development strategy and policy, sufficiently enhancing cognition to the particularity and complexity of China's marine petroleum geology,and applying new thoughts,new theories and new technologies,at the same time tackling some key technologies,it is possible to fast and effectually exploit and utilize the potential huge marine oil-gas resources of China.  相似文献   

17.
王青  赵旭  刘亚茜 《现代地质》2013,27(6):1414
Maranon、Ucayali和Madre de Dios盆地是3个弧后前陆盆地,对比研究发现:(1)古近纪和新近纪的构造运动对Ucayali盆地的影响比Maranon盆地要大。Maranon盆地西边界的古生代地层被大断层裂开,除了在老构造上有低幅度褶皱外并未明显被反转或压缩;而在Ucayali盆地内,则发育基底相关的逆冲褶皱和反转构造。(2)三叠纪期间,Maranon和Ucayali盆地的大部分地区,大的断裂和构造抬升交替保存和剥蚀着原古生代的地层,而在Madre de Dios盆地,很少有断层产生或抬升剥蚀,导致Madre de Dios盆地古生代地层比Maranon和Ucayali盆地保存较好。(3)自北向南3个盆地的主力烃源岩和主力储层的地层年代越来越老。盆地的前渊带,储层埋藏深度大和成岩作用强的特点导致储层的物性明显变差。(4)晚白垩世以来的挤压和冲断运动在3个盆地的中西部形成了大量中-高幅度的背斜、断背斜等构造圈闭。盆地东部的地层向克拉通地台方向逐层超覆,发育地层圈闭。Maranon和Ucayali盆地北部, 新近纪的构造挤压运动影响到基底,使断层贯穿至盆地基底,发育与基底相关的断层,而在Ucayali盆地的最南部发育薄皮式断层。最后,指出了3个盆地下一步勘探的领域和方向。  相似文献   

18.
准噶尔盆地南缘(简称“准南”)的构造-沉积演化历史以及原型盆地性质一直以来备受争议。依据沉积环境分析、地层对比以及沉积演化研究,结合火成岩年代学、大地构造学等研究成果,探讨了该区二叠纪—三叠纪多期次的伸展—挤压环境转换及沉积盆地性质转变。晚石炭世,准南西段处于北天山洋壳向伊犁地体俯冲的末期,沉积环境以滨浅海为主,为残留洋盆地;准南东段以半深海相碳酸盐沉积为主,发育典型的双峰式火成岩,显示为陆内的伸展环境。早二叠世,准南以滨浅海相细粒碎屑岩沉积为主,发育同沉积断裂和伸展垮塌变形构造,表现为陆内裂陷盆地的特征。中二叠世,准南仍以滨浅海相为主,但其沉积速率明显加快,沉积厚度变大,整体上表现为以热力沉降为主的坳陷盆地。晚二叠世,北天山和博格达地区普遍发育冲积扇或扇三角洲,上二叠统泉子街组和中二叠统红雁池组之间呈明显的角度不整合接触,沉积环境发生突变,均显示北天山快速冲断隆升,表明该时期准南为陆内压陷盆地。早三叠世,准南快速冲断结束,该区进入相对稳定的发展阶段,以发育滨浅湖相细粒沉积物为主,表现为弱挤压的陆内压陷盆地的特征。中晚三叠世,由于持续湖侵,沉积盆地范围进一步扩大,北天山被削高补低,准南乃至整个准噶尔盆地进入统一的内陆湖泊演化阶段,整体上以滨浅湖相—半深湖相沉积为主,表现出陆内坳陷盆地的特征。综合上述原型盆地性质和沉积环境分析,可将准南二叠纪—三叠纪构造-沉积演化划分为4个阶段:晚石炭世—中二叠世为后碰撞伸展阶段,晚二叠世为北天山挤压冲断阶段,早三叠世为弱挤压压陷和削高补低阶段,中晚三叠世为稳定拗陷和准平原化阶段。  相似文献   

19.
In South-East Asia, sedimentary basins displaying continental Permian and Triassic deposits have been poorly studied. Among these, the Luang Prabang Basin (North Laos) represents a potential key target to constrain the stratigraphic and structural evolutions of South-East Asia. A combined approach involving sedimentology, palaeontology, geochronology and structural analysis, was thus implemented to study the basin. It resulted in a new geological map, in defining new formations, and in proposing a complete revision of the Late Permian to Triassic stratigraphic succession as well as of the structural organization of the basin. Radiometric ages are used to discuss the synchronism of volcanic activity and sedimentation.The Luang Prabang Basin consists of an asymmetric NE-SW syncline with NE-SW thrusts, located at the contact between Late Permian and Late Triassic deposits. The potential stratigraphic gap at the Permian–Triassic boundary is therefore masked by deformation in the basin. The Late Triassic volcaniclastic continental deposits are representative of alluvial plain and fluvial environments. The basin was fed by several sources, varying from volcanic, carbonated to silicic (non-volcanic). U–Pb dating of euhedral zircon grains provided maximum sedimentation ages. The stratigraphic vertical succession of these ages, from ca. 225, ca. 220 to ca. 216 Ma, indicates that a long lasting volcanism was active during sedimentation and illustrates significant variations in sediment preservation rates in continental environments (from ∼100 m/Ma to ∼3 m/Ma). Anhedral inherited zircon grains gave older ages. A large number of them, at ca. 1870 Ma, imply the reworking of a Proterozoic basement and/or of sediments containing fragments of such a basement. In addition, the Late Triassic (Carnian to Norian) sediments yielded to a new dicynodont skull, attributed to the Kannemeyeriiform group family, from layers dated in between ∼225 and ∼221 Ma (Carnian).  相似文献   

20.
The Glueckstadt Graben is one of the deepest post-Permian structures within the Central European Basin system and is located right at its “heart” at the transition from the North Sea to the Baltic Sea and from the Lower Saxony Basin to the Rynkoebing–Fyn High.The Mesozoic to recent evolution is investigated by use of selected seismic lines, seismic flattening and a 3D structural model. A major tectonic event in the latest Middle–Late Triassic (Keuper) was accompanied by strong salt tectonics within the Glueckstadt Graben. At that time, a rapid subsidence took place within the central part, which provides the “core” of the Glueckstadt Graben. The post-Triassic tectonic evolution of the area does not follow the typical scheme of thermal subsidence. In contrast, it seems that there is a slow progressive activation of salt movements triggered by the initial Triassic event. Starting with the Jurassic, the subsidence centre partitioned into two parts located adjacent to the Triassic “core.” In comparison with other areas of the Central European Basin system, the Glueckstadt Graben was not strongly affected by additional Jurassic and Cretaceous events. During the late Jurassic to Early Cretaceous, the area around the Glueckstadt Graben was affected by relative uplift with regional erosion of the elevated relief. However, subsidence was reactivated and accelerated during the Cenozoic when a strong subsidence centre developed in the North Sea. During Paleogene and Quaternary–Neogene, the two centres of sedimentation moved gradually towards the flanks of the basin.The data indeed point toward a control of post-Permian evolution by gradual withdrawal of salt triggered by the initial exhaustion along the Triassic subsidence centre. In this sense, the Glueckstadt Graben was formed at least partially as “basin scale rim syncline” during post-Permian times. The present day Hamburger, East and Westholstein Troughs are the actual final state of this long-term process which still may continue and may play a role in terms of young processes and, e.g., for coastal protection.  相似文献   

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