Petroliferous basins at continental margins of paleozoic paleoseas: Communication 2. Petroliferous basins at continental margins in the Rheic, Uralian, and Central Asian paleoseas     

A. I. Konyukhov 《Lithology and Mineral Resources》2013,48(5):416-437

The continental block of the Earth’s crust was separated in the Paleozoic into two unequal parts: (i) huge supercontinent Gondwana located at high latitudes of the Southern Hemisphere and (ii) several small continents (Laurentia, Baltica, Siberia, Kazakhstan, South Chinese block, and North Chinese blocks) located at low latitudes south and north of the equator. Morphology of the Paleozoic seas between these blocks was subjected to changes (expansion and contraction) with time. Their closure was provoked by several orogenic (Taconian, Caledonian, Acadian, and Hercynian) phases. At present, relicts of these ancient orogenic structures extend as belts along the boundaries of many petroliferous basins and record the position of past seas. One of the oldest oil-and-gas deposition belts, which appeared in southern Iapetus in the Precambrian/Phanerozoic, was confined to a passive margin of Gondwana. In the Early Paleozoic, small blocks of the continental crust (Avalonia, Armorica, Perunica, Iberica, and others) were successively detached from the passive margin. This process was accompanied by the opening of a new deep basin (Rheic Sea or Paleotethys). The Uralian and Central Asian paleoseas were formed approximately at the same time. Many petroliferous basins existing now were located in the Paleozoic at the margins of these paleoseas.  相似文献   

Continental margins: Global belts of oil and gas accumulation     

A. I. Konyukhov 《Lithology and Mineral Resources》2009,44(6):513-530

Most of recent oil- and gas-bearing basins are incorporated in the group of five belts of oil-and-gas accumulation. They are confined to continent/ocean transition zones, which existed in the Cenozoic. Three belts (Tethyan, Gondwanan, and Laurasian) are latitudinal structures that include continental margins in the Atlantic, Indian, and Arctic oceans. The other two belts are elongated in the N-S direction and located in the western and eastern peripheral parts of the Pacific Ocean. Taken together, they unite basins with 75 to 80% of oil reserves discovered to date in our planet.  相似文献   

Continental margins as global oil and gas accumulation belts: The West Pacific belt     

A. I. Konyukhov 《Lithology and Mineral Resources》2010,45(5):465-485

Most present-day oil- and gas-bearing (petroliferous) basins are localized in one of the five global oil and gas accumulation belts confined to continent-ocean transition zones that existed in the Mesozoic and Cenozoic. Two meridional belts are located in the western and eastern peripheral zones of the Pacific Ocean with intense tectonic activity during the major part of the Mesozoic and Cenozoic. The activity was reflected in extension of the continental crust, spreading of the oceanic crust, rapid subsidence of individual crustal blocks, volcanism, and formation of large batholiths and accretionary prisms. In this belt, the fore-arc, back-arc, inter-arc, and marginal riftogenic sedimentary basins are petroliferous.  相似文献   

Continental margins as global oil-accumulation belts: The Gondwana belt     

A.?I.?KonyukhovEmail author 《Lithology and Mineral Resources》2010,45(4):358-376

Most present-day petroliferous basins are localized in one of the five global oil and gas accumulation belts confined to continent—ocean transition zones that existed in the Mesozoic and Cenozoic. The Gondwana belt is formed by basins developed on continental margins of the Indian Ocean and South Atlantic (Konyukhov, 2009). All of them are riftogenic in nature and were formed during either the Late Paleozoic (basins on continental margins of the Indian Ocean) or the Late Mesozoic (basins in peripheral zones of the South Atlantic). During the most part of geological history, they were located in zones dominated by the humid climate, which determined the prevalent role of terrigenous rocks in their sedimentary cover.  相似文献   

Source rocks in sedimentary basins of continental margins in the early paleozoic     

A. I. Konyukhov 《Lithology and Mineral Resources》2014,49(3):250-271

During the Paleozoic, epochs with the relatively cold climate alternated with epochs marked by significant warming. Moreover, cooling epochs were characterized by the substantial sea level fall, while warming was accompanied by its rapid rise. In many basins located at margins of Laurentia, Baltica, and the North China continental block, such an alternation is reflected in the structure of sedimentary sequences and the lateral/vertical distribution of reservoirs, confining beds, and source rocks. Despite the fact that sediments with high concentrations of sapropelic OM accumulated in different periods, their distribution areas on continents and their margins became highly reduced during cold epochs, when these sediments filled mostly rift troughs and foreland basins. After the colonization of land by higher plant communities in the Carboniferous and Permian sediments deposited during cold epochs, the humic material became an important constituent of OM in the source rock sequences.  相似文献   

Continental margins: Global belts of oil-and-gas accumulation. The Caribbean-pacific belt     

A. I. Konyukhov 《Lithology and Mineral Resources》2011,46(6):528-545

Among petroliferous regions of the world, a specific place is occupied by sedimentary basins confined to continental margins at the eastern periphery of the Pacific Ocean and in the Caribbean Sea. In the Cenozoic and Quaternary, this region was dominated by tectonic activity manifested as compression, movements along large fault systems (primarily, strike-slip faults), formation of mountain chains, appearance of thick accretion prisms and foothills, and development of volcanism at certain stages. The petroliferous structures of the region are mainly represented by fore-arc sedimentary basins complicated in some places by fore- and backdeeps.  相似文献   

The ancient continental margins of the North American and South American plates and regularities in the occurrence of oil and gas accumulations in them     

A. Zabanbark  L. I. Lobkovskii 《Doklady Earth Sciences》2012,442(2):220-225

Various stages of the development of sedimentary basins along the ancient margins of the North American and South American plates are considered. It is shown that the potential of the oil-and-gas bearing is related to a certain stage of evolution of the basins. For the margins of the North American plate, it is the first stage of development in the structure of the ancient Paleozoic continental margins that developed under passive tectonic conditions. For the basins along the ancient margins of the South American plate, it is the second stage, which is the stage of the formation and development of foredeeps overlaid on the earlier structures. An interesting regularity is displayed: than younger the folding-mountain structures that originated in the distal parts of the continental margins, than greater the age range of source rocks in the sedimentary basins preserved there.  相似文献   

Transects of the ancient and modern continental margins of eastern Canada     

Richard T. Haworth  Charlotte E. Keen  H. Williams 《Tectonophysics》1984,109(1-2)

Rocks of the west flank of the northern Appalachian Orogen (miogeocline) record the history of the late Precambrian-early Paleozoic passive continental margin of Eastern North America. The ancient margin was destroyed by ophiolite obduction and arc collision during the Ordovician Taconic Orogeny. The present sinuous form of the miogeocline is interpreted to reflect ancient promontories and re-entrants of a previous orthogonal margin bounded by rifts and transforms.Four major terranes are recognized east of the miogeocline in Newfoundland and Nova Scotia. From west to east, these are the Dunnage, Gander, Avalon and Meguma. The Dunnage and Gander terranes were linked to the miogeocline during the Middle Ordovician Taconian Orogeny. The Avalon terrane arrived later, possibly during the mid-Paleozoic Acadian Orogeny. The Meguma terrane of southern Nova Scotia had docked with the Avalon terrane by Carboniferous time. The Dunnage terrane contains arc volcanics which lie above an ophiolitic substrate. The Gander terrane comprises a thick sequence of clastic sedimentary rocks, underlain by basement rocks with continental affinities. It has been interpreted as a continental margin, perhaps once on the eastern side of the Paleozoic Iapetus ocean. The Avalon terrane consists of belts of sedimentary and volcanic rocks which are probably underlain by Grenvillian basement. Its tectonic affinities are unclear. The Meguma terrane comprises a thick sequence of sediments, derived from the south-east. It is found only in southeastern Atlantic Canada. The boundaries between terranes are compressional in the west and steep, transcurrent faults in the east.The surface extent of the geological terranes is grossly correlative with deep structural zones, although no direct evidence exists for linking the two because most surface structures can be traced geophysically to only a few kilometres depth. A striking feature of the deep crustal structure is a lower, high velocity crustal layer beneath the Dunnage and Gander terranes.The modern margin of Atlantic Canada developed by rifting and by transform motion between adjacent continents. Stretching and thinning of the lithosphere, and the consequent production of basaltic magma that in places intrudes or underplates the thinned continental crust, are the most likely processes responsible for the evolution of the modern margin. These processes predict the observed deep sedimentary basins along the margin, the thinning of continental crust, and the high seismic velocities found within the ocean-continent transition zones.Rifting adjacent to Nova Scotia began in Late Triassic-Early Jurassic time between the present African and North American plates. These plate motions are also responsible for the major transform margin south of the Grand Banks. Separation between Iberia and the eastern Grand Banks occurred in mid-Cretaceous time, before the Late Cretaceous opening of the Labrador Sea. While the rifted segments of the margin exhibit deep sedimentary basins and thinned continental crust, the Grand Banks transform segment is characterized by a sharp transition zone and a relatively thin sediment cover. Numerous volcanic seamounts are built on the ocean crust adjacent to this transform segment.Mimicry of Paleozoic promontories and re-entrants by modern rift and transform margin segments, the location of Mesozoic sedimentary basins on ancestral Appalachian structures, and the reactivation and propagation of major Precambrian and Paleozoic structural boundaries during the latest phase of ocean opening attest to ancestral controls of the modern margins.The rift phase of both the ancient and modern passive margins is characterized by volcanism, mafic dike intrusion and by the development of basins filled with clastic sediments. The drift phase of both the ancient margin and the present Nova Scotia margin is marked by a change in sedimentary environment, such that carbonates replaced the rift phase clastic sediments. Two of the markers used to delineate the ancient ocean-continent transition zone; carbonate banks and steep gravity anomaly gradients, should be used with caution as the modern analogs of these markers may lie 100 km or more of this transition zone. Furthermore, it is naive to view the ancient transition as simple and narrow, for the modern margins exhibits complex transition zones between 30 and 300 km wide.In general, the evolution of the ancient and modern passive margins appear to be remarkably similar. Predictably, closing the present Atlantic will mimic the evolution of the Appalachian Orogen.  相似文献   

Continental growth at convergent margins facing large ocean basins: a case study from Mesozoic convergent-margin basins of Baja California, Mexico     

Cathy Busby   《Tectonophysics》2004,392(1-4):241

Mesozoic rocks of the Baja California Peninsula form one of the most areally extensive, best-exposed, longest-lived (160 my), least-tectonized and least-metamorphosed convergent-margin basin complexes in the world. This convergent margin shows an evolutionary trend that may be typical of arc systems facing large ocean basins: a progression from highly extensional (phase 1) through mildly extensional (phase 2) to compressional (phase 3) strain regimes. This trend is largely due to the progressively decreasing age of lithosphere that is subducted, which causes a gradual decrease in slab dip angle (and concomitant increase in coupling between lower and upper plates), as well as progressive inboard migration of the arc axis.This paper emphasizes the usefulness of sedimentary and volcanic basin analysis for reconstructing the tectonic evolution of a convergent continental margin. Phase 1 consists of Late Triassic to Late Jurassic oceanic intra-arc to backarc basins that were isolated from continental sediment sources. New, progressively widening basins were created by arc rifting and sea floor spreading, and these were largely filled with progradational backarc arc-apron deposits that record the growth of adjacent volcanoes up to and above sea level. Inboard migration of the backarc spreading center ultimately results in renewed arc rifting, producing an influx of silicic pyroclastics to the backarc basin. Rifting succeeds in conversion of the active backarc basin into a remnant backarc basin, which is blanketed by epiclastic sands.Phase 1 oceanic arc–backarc terranes were amalgamated by Late Jurassic sinistral strike slip faults. They form the forearc substrate for phase 2, indicating inboard migration of the arc axis due to decrease in slab dip. Phase 2 consists of Early Cretaceous extensional fringing arc basins adjacent to a continent. Phase 2 forearc basins consist of grabens that stepped downward toward the trench, filled with coarse-grained slope apron deposits. Phase 2 intra-arc basins show a cycle of (1) arc extension, characterized by intermediate to silicic explosive and effusive volcanism, culminating in caldera-forming silicic ignimbrite eruptions, followed by (2) arc rifting, characterized by widespread dike swarms and extensive mafic lavas and hyaloclastites. This extensional-rifting cycle was followed by mid-Cretaceous backarc basin closure and thrusting of the fringing arc beneath the edge of the continent, caused by a decrease in slab dip as well as a possible increase in convergence rate.Phase 2 fringing arc terranes form the substrate for phase 3, which consists of a Late Cretaceous high-standing, compressional continental arc that migrated inboard with time. Strongly coupled subduction resulted in accretion of blueschist metamorphic rocks, with development of a broad residual forearc basin behind the growing accretionary wedge, and development of extensional forearc (trench–slope) basins atop the gravitationally collapsing accretionary wedge. Inboard of this, ongoing phase 3 strongly coupled subduction, together with oblique convergence, resulted in development of forearc strike-slip basins upon arc basement.The modern Earth is strongly biased toward long-lived arc–trench systems, which are compressional; therefore, evolutionary models for convergent margins must be constructed from well-preserved ancient examples like Baja California. This convergent margin is typical of many others, where the early to middle stages of convergence (phases 1 and 2) create nonsubductable arc–ophiolite terranes (and their basin fills) in the upper plate. These become accreted to the continental margin in the late stage of convergence (phase 3), resulting in significant continental growth.  相似文献   

Ancient continental margins and comparative analysis of their oil-and-gas bearing     

A. Zabanbark  V. G. Kaz’min  L. I. Lobkovskii 《Doklady Earth Sciences》2010,431(1):308-311

Analysis of peculiarities in the distribution of hydrocarbon accumulations within the basins of Phanerozoic continental margins, which had completed their evolution, and complicated peripheral regions of ancient Laurasian and Gondwanian platforms nowadays, has enabled us to reveal certain regularities related to two stages in the evolution of sedimentary basins. The first stage of evolution of sedimentary basins (period of existence of the continental margin proper) is related to large accumulations of fluid and gaseous hydrocarbons in the margins of continents belonging to the Laurasian megablock; for the margins of continents belonging to Gondwana, this period was reflected in the formation of large gas accumulation only (in the Permian). At the second stage of sedimentary basin evolution, large oil and gas accumulations were formed in areas associated with fore deeps, which were laid in the boundary of the Gondwanian platforms and fold belts. In comparison, in fore deeps that emerged in the marginal parts of Laurasian platforms, less significant accumulations of fluid and gaseous hydrocarbons were found (Table 1). The results of comparative analysis in oil-and-gas bearing basins located in the margins of the Laurasian and Gondwanian megablocks would help in purposeful exploratory works for oil and gas.  相似文献   

The main causes of the occurrence of carbonate cementation zones in the strata of oil- and gas-bearing basins     

E. E. Karnyushina 《Moscow University Geology Bulletin》2012,67(5):320-322

The results of studies of sedimentary strata carbonatization in oil- and gas-bearing basins are generalized. The sources of CO₂, H₂CO₃, and organic acids, which regulate the carbonate balance in stratum waters at the stages of diagenesis and catagenesis, as well as under the influence of superposed processes, including those with the participation of microorganisms, are considered. The scale of secondary carbonatization of deposits in the zone of water-oil contacts and in the interval of hydrothermal action is estimated.  相似文献   

Oil and Gas Potential of Deep- and Ultradeep-Water Zones of Continental Margins   总被引：3，自引：0，他引：3  

Khain  V. E.  Polyakova  I. D. 《Lithology and Mineral Resources》2004,39(6):530-540

Oil- and gas-bearing basins of the World Ocean spreading to the continental shelf and foothill are considered. Large hydrocarbon resources, including oil pools have been discovered in the deep-water basins. The basins are confined to passive continental margins and characterized by the common mechanism of formation. Oil and gas (hereafter, petroleum) generation and accumulation are dictated by the optimum specifics of source and reservoir rocks accumulated under favorable conditions of rifts and deep-sea fans. Halokinesis played an important role in the formation of traps and migration of hydrocarbons. The global experience shows that the northern, eastern, and southern shelves of the Russian seas, as well as their continental slopes and foothills, have a big petroleum potential.  相似文献   

Sedimentary basins of passive margins filled with sediments of river deltas and submarine fans     

A. I. Konyukhov 《Lithology and Mineral Resources》2008,43(6):507-519

Rivers transport huge quantities of terrigenous material mobilized in their drainage areas and represented by rock fragments and grains of quartz, feldspars, and other weathering-resistant minerals. Large volumes of fine clay particles and organic components in the form of suspended matter and dissolved salts are also transported from the land to seas and oceans. This material is deposited in river deltas located on shelves and submarine fans, which are formed on the continental slope and at its foothill. Thick lenses of deltaic and submarine fan sediments turn gradually into oil-and gas-bearing basins, the largest among which is the Gulf of Guinea basin.  相似文献   

Continental margins: Global belts of oil-and-gas accumulation,Laurasian belt     

A. I. Konyukhov 《Lithology and Mineral Resources》2010,45(2):136-153

Most recent oil-and-gas-bearing (petroliferous) basins are members of one of the five oil-and-gas accumulation belts confined to the Mesozoic and Cenozoic continent/ocean transition zones. The Laurasian belt includes continental margins in the northern Atlantic and Arctic oceans that accommodate several large petroliferous basins.  相似文献   

Rifted arch basins and post-breakup rim basins on passive continental margins     

J.J Veevers 《Tectonophysics》1977,41(4)

In its evolution by plate divergence to a passive continental margin, a continental arch marked by narrow rift valleys (intra-arch basins) and flanked by broad basins (inter- and extra-arch basins) is most likely to break up along a rift valley boundary fault. The resulting dismembered arch at the continental margin is a rim that constitutes the oceanward flank of a rim basin, and the rim basin succeeds one or other of the basins related to the previous arch. In offshore Western Australia, the juxtaposition of Mesozoic reservoir rock at a rift shoulder and source rock of the succeeding rim basin provide a mechanism for concentrating a large gas deposit.  相似文献   

南美洲含油气盆地和油气分布综述   总被引：2，自引：2，他引：0  

白国平  秦养珍 《现代地质》2010,24(6):1102-1111

南美洲是世界上的主要油气产区之一,近年来取得了一系列重大勘探突破。2007年以来,桑托斯盆地盐下一系列巨型油气田的发现表明南美洲,特别是被动陆缘盆地深水盐下层系有着巨大的勘探潜力。以获取的最新油气田储量资料为基础,探讨了南美洲的油气资源在不同类型盆地、不同地区和不同层系的分布特征。统计分析表明前陆盆地油气最富集,其次是被动陆缘盆地。南美洲的前陆盆地沿安第斯山展布,南段和北段为新生代前陆盆地,中段为古生代前陆盆地。南段、中段和北段前陆盆地的主要储集层分别为侏罗系-白垩系、石炭系和白垩系-新近系。经历了被动陆缘演化阶段的前陆盆地是南美洲油气最富集的盆地,典型的代表为东委内瑞拉盆地和马拉开波盆地。被动陆缘盆地分布于南美洲大陆的东部沿海区,油气主要聚集于白垩系、古近系和新近系。在被动陆缘盆地中,发育有蒸发岩的盆地油气更为富集,坎波斯盆地和桑托斯盆地是这类盆地的典型代表。  相似文献   

Sedimentary basins,regularities of their formation and classification principles: Communication 1. Sedimentation basins     

V. N. Kholodov 《Lithology and Mineral Resources》2010,45(1):1-23

Two types of sedimentary basins are proposed: sedimentation basins and rock formation basins (rock basins). Such an approach reflects a complete cycle of the sedimentary process ranging from the stage of material mobilization and transport to the stage of accumulation of sediments, their transformation into sedimentary rocks, and formation of associated mineral deposits. Sedimentation basins are divided into lakes, intracontinental and marginal seas, and oceans, where phase differentiation of matter proceeds in different manners. It is shown that eupelagic and miopelagic clays, analogues of which are missing from Paleozoic sequences, represent the main indicator of recent sedimentation in the Word Ocean. It is stated that each sedimentation basin is characterized by a specific association of sedimentary mineral deposits.  相似文献   

Palaeogeographic and geodynamic evolution of the Gondwana continental margins during the Cambrian     

Pierre Courjault-Radé  Françoise Debrenne  Anna Gandin 《地学学报》1992,4(6):657-667

During the Cambrian, two types of continental margins occurred around Gondwana. The eastern margin (Antarctica, Australia and southern South America) was characterized by a narrow continental shelf with a steep slope separating the shallow water environment from a deep-oceanic one accompanied by mafidultramafic volcanics. The western margin was characterized by a wider continental shelf, probably passing gradually to an unknown outer basin. This comprised three main domains: the Asiatic shelf, composed of distinct cratonic blocks, presumably separated from each other by deeper-water/ volcanic intracontinental basins; the European shelf, characterized by the development of shallow intracontinental siliciclastic basins; and the Americanc-African shelf, morphologically and depositionally uniform. The distinction of these two Gondwana continental margins expresses their different geodynamic behaviour during Cambrian extensional tectonics. In fact, the sedimentary/palaeogeographic evolution, suggests the establishment of an active Pacific-like margin in the eastern domain, and the tentative establishment of a divergent Atlantic-like margin, in the westem one.  相似文献   

Tectonotype of volcanic passive margins in the Norwegian-Greenland region     

E. N. Melankholina 《Geotectonics》2008,42(3):225-244

A tectonotype of volcanic passive margins exemplified in the conjugate Norwegian and East Greenland margins is considered, with discussion of the Paleogene igneous complexes and the regional rift structure before continental breakup. Fragments of asymmetrical rift have been retained on both sides of the ocean. Large Cretaceous pre-rift sedimentation basins marking the initial stage of the ocean opening are included into the passive margin as well. The continental breakup was accompanied by intense basaltic magmatism over a short time span. This magmatic episode was distinguished by (1) the formation of widespread plateau-basalt complexes on continents and in near-shore areas of the ocean; (2) the development of thick lava series that are recorded in seaward dipping reflector wedges; (3) thick high-velocity lower crust, resulting from magmatic underplating; (4) asymmetrical accretion of the crust and structure formation. The discussion is based on published seismic data and reference sections selected for each margin with consideration of the composition and thickness of the igneous rocks, their lateral variations, source composition, and eruption and crust formation conditions. The characteristic feature of both sections is the two-member structure of volcanic complexes with substantial geochemical differences between the rocks from the lower and upper parts of the section, which correspond to the pre-breakup and breakup phases. At the initial phase, small magma volumes were melted out from the lithosphere. The geochemical signatures of the upper parts of the sections testify to the melting of the asthenospheric mantle. Their spatiotemporal variations reflect the ascent and melting of the deep plume, which was active during and after continental breakup. In the Greenland area, near the central part of the plume, a N-MORB-type mantle magma source gave way to a depleted Iceland-type mantle, while apart from the central part of the plume, its effect is expressed only in the enormous volume of mantle-derived melt without migration of its source. A variety of evidence is provided for the plume’s activity: the great thickness of the volcanic complexes and the relatively stable composition of the melt; the elevated temperature in the mantle; the specific geochemistry of the breakup-related lavas and their lateral zoning; conclusions on the necessity of dynamic support of volcanic eruptions; and recent results of seismographic tomography. The continental breakup inherited a system of older sedimentary basins in the zone of prolonged extension of the lithosphere in the North Atlantic. The continuous dynamic support of extension was most likely provided by long-term ascent of the Iceland plume. The comparison of the considered tectonotype with other volcanic and non-volcanic margins opens the way to further elucidation of the geodynamic processes responsible for the ocean opening.  相似文献   

Evolution of sedimentary basins from Mesozoic times in Australia's continental slope and shelf     

John C. Branson 《Tectonophysics》1978,48(3-4)

Three basic tectonic styles are described from structural trends and sedimentary sequences within sedimentary basins in the Australian continental slope and shelf. These tectonic styles are related to sea-floor spreading events and plate-tectonic movements within the adjacent ocean floor. The same tectonic styles occur within sedimentary basins of different ages; Mesozoic and early Tertiary basins contain rift valley sequences and late Cainozoic basins contain geosynclinal sedimentary suites.Northwestern, western and southern continental margins reflect spreading events explained by an Atlantic-type model in which there are rift-valley sedimentary sequences. The oldest rift valleys in the northwest and the youngest rifts in the south formed ahead of Gondwanaland break-up. After sea-floor spreading commenced, the rate of continental margin collapse varied from place to place. The eastern and northeastern slopes and shelves border marginal seas and do not contain recognizable rift-valley sequences, except for tensional splays (triple junctions) in the Tasman Sea. Short-lived spreading within marginal seas started in the Late Cretaceous in the south and in the Paleocene in the northeast. The tectonism of the northern margin is mainly recorded on land in Timor, Irian Jaya and Papua New Guinea, where, in the Neogene to Holocene, the Australian continent collided with the Asian Plate at the Banda Arc and the sub-plates of the western Pacific at the Louisiade and Bismarck Arcs.  相似文献