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1.
V. M. Grannik 《Doklady Earth Sciences》2012,445(2):934-938
It has been established that volcanic rocks of the Schmidt, Rymnik, and Terpeniya terranes are fragments of the compound Early to Late Cretaceous-Paleogene East Sakhalin island arc system of the Sea of Okhotsk region. This island arc paleosystem was composed of back-arc volcano-plutonic belt, frontal volcanic island arc, fore-arc, inter-arc, and back-arc basins, and the Sakhalin marginal paleobasin. The continental volcanic rocks dominate in the back-arc volcano-plutonic belt and frontal volcanic island arc. The petrochemical composition of basalts, basaltic andesites, andesites, and trachytes from the frontal island arc formed in submarine conditions are typical of oceanic island arc or marginal sea rocks (IAB). The petrochemical composition of volcanic rocks from the island arc structures indicates its formation on the heterogeneous basement including the continental and oceanic blocks. 相似文献
2.
V. P. Simanenko S. V. Rasskazov T. A. Yasnygina L. F. Simanenko A. A. Chashchin 《Russian Journal of Pacific Geology》2011,5(1):26-46
The variations of petrogenic oxides and trace elements have been studied in the Cretaceous volcanic rocks recovered by a deep
borehole from the depth interval of 1253–4011 m on Moneron Island. The volcanic section is subdivided into two complexes:
the Early Cretaceous and Late Cretaceous. The rocks of the Early Cretaceous Complex occur below 1500 m. Chemically, they belong
to low-potassium island arc tholeiites, and their trace element distribution suggests their formation in a suprasubduction
mantle wedge under the influence of water fluids that were subsequently released from subducted sediments and oceanic plate
during the dehydration of subducted sedimentary rocks and oceanic basalts and, finally, mainly from basalts. The Early Cretaceous
basalts from the borehole are interpreted as ascribing to the frontal part of the Moneron-Samarga island arc system. The volcanic
rocks of the Late Cretaceous Complex are situated at depths above 1500 m. They also were formed in a suprasubduction setting,
but already within the East Sikhote-Alin continental-margin volcanic belt that was initiated after the accretion of the Moneron-Samarga
island arc system to the Asian continent. The island-arc section of the Moneron borehole contains basaltic andesite dikes,
which are geochemically comparable with the Early-Middle Miocene volcanic rocks of Southwestern Sakhalin. 相似文献
3.
New data on the chemical and rare-element composition and age of the rocks referred earlier to the Iruney suite of the Kamchatka Isthmus are received. In the recent structure these rocks compose the structural–strata complexes of the nappe-folded Lesnovsky Rise. Radiolarian analysis data substantiate that the deposits belonging to the Ening series and the middle and upper parts of the Iruney suite were formed in a single sedimentation basin in the Campanian time. The discovery of a new occurrence of Prunobrachidae representatives on the Kamchatka Peninsula allows us to draw wide interregional correlations and reconstruct the sedimentation conditions. The studied volcanites relate to different igneous series and were formed in geodynamic conditions of the marginal sea and the volcanic arc. The igneous rocks of the Ening stratum are similar to the N-MOR and OI basalts that were formed within the marginal sea (Iruney Marginal Sea) basin. The Upper Cretaceous formations of the eastern slope of the Sredinny Range were formed within the volcanic rise with the island-arc type of volcanism. The younger Eocene igneous rocks of the neo-autochthon (granites and granodiorites) and the volcanic rocks of the Kinkil suite mark a new orogenic stage of development of the Kamchatka margin. 相似文献
4.
The thick (up to 17000 m) sequence of Albian, Upper Cretaceous, Paleogene, and Neogene ter-rigenous and less abundant volcanic rocks was deposited with breaks in sedimentation but without any tectonic rearrangements within the paleobasin bounded by the West Sakhalin and Tym-Poronai fault systems in the west and the east, respectively. The intensity of sagging progressively increased with time and reached a maximum in the late Miocene and Pliocene. The contemporary structure of the terrane started to form in the Pleistocene and has continued to form until now in the course of local inversion under the setting of dominating regional compression oriented in the ENE-E direction (60°–90°). The local indications of the SE-NW compression presumably are a result of pressure from the side of the Pacific Plate subducted beneath the Kurile-Kamchatka arc. Compression in these competing directions developed and develops contemporaneously within the same region. 相似文献
5.
New Data on the Composition of Cretaceous Volcanic Rocks of the Alazeya Plateau,Northeastern Yakutia
This work presents new data on the composition of volcanics, developed within the Alazeya Plateau of the Kolyma–Indigirka fold area (Northeast Russia), which indicate essential differences in their composition and, accordingly, different geodynamic settings of the formation of rocks. The studied igneous rocks are subdivided into two groups. Volcanics of the first group of the Late Cretaceous age, which are represented by differentiated volcanic rock series (from andesitobasalts to dacites and rhyolites), were formed under island arc conditions in the continent–ocean transition zone. Volcanics of the second group are ascribed to the tholeiitic series and were formed under the other geodynamic setting, which is associated with the regime of extension and riftogenesis, manifested in the studied area probably at the later stage. 相似文献
6.
The Kiselyovka–Manoma accretionary complex formed at the end of the Early Cretaceous during subduction of the Pacific oceanic plate underneath the Khingan–Okhotsk active continental margin along the east of Eurasia. It is composed of Jurassic–Early Cretaceous oceanic chert, siliceous mudstone, and limestone that include a significant amount of basic volcanic rocks. The known and newly obtained data on the petrogeochemistry of the Jurassic and Early Cretaceous basalt from various parts of the accretionary complex are systemized in the paper. Based on the comprehensive analysis of these data, the possible geodynamic settings of the basalt are considered. The petrogeochemical characteristics provide evidence for the formation of basalt in different parts of the oceanic floor within the spreading ridge, as well as on oceanic islands far from the ridge. The basalts of oceanic islands are mostly preserved in the accretionary complex. The compositional variations of the basalts may be controlled by the different thickness of the oceanic lithosphere on which they formed. This is explained by the varying distances of the lithosphere from the spreading zone. 相似文献
7.
中部拉萨地体南侧吉瓦地区早白垩世则弄群火山岩的发现及意义 总被引:1,自引:0,他引:1
西藏尼玛县吉瓦地区措勤-多瓦后陆拗陷带内分布的火山岩LA-ICP-MS锆石U-Pb年龄为120.3~126.5Ma左右,重新厘定为早白垩世则弄群,否定了前人归属为上新世乌郁群(N2wy)及始新世帕那组(E2p)的认识。岩石以酸性火山岩为主,中基性火山岩为辅,酸性岩类主要为火山碎屑岩类和熔岩类,典型岩石类型为流纹质熔结凝灰岩和流纹岩等,中基性岩主要为玄武安山岩,安山玄武岩等,杏仁构造普遍发育。研究区大量的流纹质熔结凝灰岩的出现反映了吉瓦地区的火山岩主要为陆相火山喷发形成。地球化学特征显示轻稀土富集,负Eu异常明显,富集K、Rb、Th、U等大离子亲石元素,相对亏损Nb、Ta、P、Ti等高场强元素。酸性火山岩具有A型花岗质岩浆岩特征,基性岩具有板内玄武岩亲缘性,这一特征可能与班公湖-怒江洋壳岩石圈南向俯冲过程中发生的板片断离有关。中部拉萨地体南侧早白垩世火山岩的发现,使班公湖-怒江洋壳南向俯冲在晚侏罗世-早白垩世的岩浆活动在原来的基础上向南延伸70~80km,火山岩地层时代的重新归位对研究冈底斯带早白垩世地球动力学背景及建立地质年代学格架提供了新的约束资料,具有重要的科学意义。吉瓦地区早白垩世则弄群火山岩可能受到了班公湖-怒江特提斯洋壳向南、雅鲁藏布江洋壳向北的双向俯冲制约。 相似文献
8.
Tahmineh Pirnia Emilio Saccani Ghodrat Torabi Marco Chiari Spela Gorican Edoardo Barbero 《地学前缘(英文版)》2020,11(1):57-81
The Nain and Ashin ophiolites consist of Mesozoic melange units that were emplaced in the Late Cretaceous onto the continental basement of the Central-East Iran microcontinent(CEIM).They largely consist of serpentinized peridotites slices;nonetheless,minor tectonic slices of sheeted dykes and pillow lavas-locally stratigraphically associated with radiolarian cherts-can be found in these ophiolitic melanges.Based on their whole rock geochemistry and mineral chemistry,these rocks can be divided into two geochemical groups.The sheeted dykes and most of the pillow lavas show island arc tholeiitic(IAT)affinity,whereas a few pillow lavas from the Nain ophiolites show calc-alkaline(CA)affinity.Petrogenetic modeling based on trace elements composition indicates that both IAT and CA rocks derived from partial melting of depleted mantle sources that underwent enrichment in subduction-derived components prior to melting.Petrogenetic modeling shows that these components were represented by pure aqueous fluids,or sediment melts,or a combination of both,suggesting that the studied rocks were formed in an arc-forearc tectonic setting.Our new biostratigraphic data indicate this arc-forearc setting was active in the Early Cretaceous.Previous tectonic interpretations suggested that the Nain ophiolites formed,in a Late Cretaceous backarc basin located in the south of the CEIM(the so-called Nain-Baft basin).However,recent studies showed that the CEIM underwent a counter-clockwise rotation in the Cenozoic,which displaced the Nain and Ashin ophiolites in their present day position from an original northeastward location.This evidence combined with our new data and a comparison of the chemical features of volcanic rocks from different ophiolites around the CEIM allow us to suggest that the Nain-Ashin volcanic rocks and dykes were formed in a volcanic arc that developed on the northern margin of the CEIM during the Early Cretaceous in association with the subduction,below the CEIM,of a Neo-Tethys oceanic branch that was existing between the CEIM and the southern margin of Eurasia.As a major conclusion of this paper,a new geodynamic model for the Cretaceous evolution of the CEIM and surrounding Neo-Tethyan oceanic basins is proposed. 相似文献
9.
K. Wakita 《Journal of Asian Earth Sciences》2000,18(6)
The geology of Cretaceous accretionary–collision complexes in central Indonesia is reviewed in this paper. The author and his colleagues have investigated the Cretaceous accretionary–collision complexes by means of radiolarian biostratigraphy and metamorphic petrology, as well as by geological mapping. The results of their work has revealed aspects of the tectonic development of the Sundaland margin in Cretaceous time. The Cretaceous accretionary–collision complexes are composed of various tectonic units formed by accretionary or collision processes, forearc sedimentation, arc volcanism and back arc spreading. The tectonic units consist of chert, limestone, basalt, siliceous shale, sandstone, shale, volcanic breccia, conglomerate, high P/T and ultra high P metamorphic rocks and ultramafic rocks (dismembered ophiolite). All these components were accreted along the Cretaceous convergent margin of the Sundaland Craton. In the Cretaceous, the southeastern margin of Sundaland was surrounded by a marginal sea. An immature volcanic arc was developed peripherally to this marginal sea. An oceanic plate was being subducted beneath the volcanic arc from the south. The oceanic plate carried microcontinents which were detached fragments of Gondwanaland. Oceanic plate subduction caused arc volcanism and formed an accretionary wedge. The accretionary wedge included fragments of oceanic crust such as chert, siliceous shale, limestone and pillow basalt. A Jurassic shallow marine allochthonous formation was emplaced by the collision of continental blocks. This collision also exhumed very high and ultra-high pressure metamorphic rocks from the deeper part of the pre-existing accretionary wedge. Cretaceous tectonic units were rearranged by thrusting and lateral faulting in the Cenozoic era when successive collision of continental blocks and rotation of continental blocks occurred in the Indonesian region. 相似文献
10.
歧口凹陷侏罗系火成岩主要以中-酸性的流纹岩、粗面岩和粗面安山岩为主,白垩系主要为中-基性的粗面玄武岩和玄武质粗面安山岩,第三系火成岩以粗面玄武岩、碱性玄武岩及辉绿岩为主。同位素定年结果获得白垩系玄武岩的年龄为133±20 Ma,安山岩和粗安岩年龄分别为111.8±0.9 Ma和122.1±3.1 Ma,第三系辉绿岩年龄为16.57±0.23 Ma。地球化学特征显示,侏罗系火成岩相对低钛、高碱和钠、低铁镁,轻重稀土元素强烈分馏、微量元素相对富集LILE、贫化HFSE、亏损Nb和Ti、P,部分高Sr、低Yb,总体指示为挤压环境下加厚地壳物质的熔融产物,白垩系火成岩中等钛和碱的含量,高钠、铁和镁,稀土和微量元素显示其来自于伸展背景的富集地幔源,但受到陆壳物质的混染,第三系火成岩高钛含量、中等碱含量但变化大、高钠、富铁镁,轻重稀土元素分馏弱到中等、微量元素富集LILE和HFSE,同样来自板内伸展环境的富集地幔源的产物。表明歧口凹陷构造转换发生在晚侏罗世和早白垩世之间。 相似文献
11.
A GIS layout of the map of recent volcanism in North Eurasia is used to estimate the geodynamic setting of this volcanism.
The fields of recent volcanic activity surround the Russian and Siberian platforms—the largest ancient tectonic blocks of
Eurasia—from the arctic part of North Eurasia to the Russian Northeast and Far East and then via Central Asia to the Caucasus
and West Europe. Asymmetry in the spatial distribution of recent volcanics of North Eurasia is emphasized by compositional
variations and corresponding geodynamic settings. Recent volcanic rocks in the arctic part of North Eurasia comprise the within-plate
alkaline and subalkaline basic rocks on the islands of the Arctic Ocean and tholeiitic basalts of the mid-ocean Gakkel Ridge.
The southern, eastern, and western volcanic fields are characterized by a combination of within-plate alkaline and subalkaline
basic rocks, including carbonatites in Afghanistan, and island-arc or collision basalt-andesite-rhyolite associations. The
spatial distribution of recent volcanism is controlled by the thermal state of the mantle beneath North Eurasia. The enormous
mass of the oceanic lithosphere was subducted during the formation of the Pangea supercontinent primarily beneath Eurasia
(cold superplume) and cooled its mantle, having retained the North Pangea supercontinent almost unchanged for 200 Ma. Volcanic
activity was related to the development of various shallow-seated geodynamic settings and deep-seated within-plate processes.
Within-plate volcanism in eastern and southern North Eurasia is controlled, as a rule, by upper mantle plumes, which appeared
in zones of convergence of lithospheric plates in connection with ascending hot flows compensating submergence of cold lithospheric
slabs. After the breakdown of Pangea, which affected the northern hemisphere of the Earth insignificantly, marine basins with
oceanic crust started to form in the Cretaceous and Cenozoic in response to the subsequent breakdown of the supercontinent
in the northern hemisphere. In our opinion, the young Arctic Ocean that arose before the growth of the Gakkel Ridge and, probably,
the oceanic portion of the Amerasia Basin should be regarded as a typical intracontinental basin within the supercontinent
[48]. Most likely, this basin was formed under the effect of mantle plumes in the course of their propagation (expansion,
after Yu.M. Pushcharovsky) to the north of the Central Atlantic, including an inferred plume of the North Pole (HALIP). 相似文献
12.
L. AGUIRRE 《Journal of Metamorphic Geology》1993,11(3):437-448
Abstract Pumpellyites in pervasively altered basic to intermediate rocks from three Cretaceous Andean volcanic sequences, the Colombian Diabasic Group, the Ecuadorian-Peruvian Celica Formation/Casma Group and the Chilean Ocoite Group, were studied to test their compositional behaviour in relation to changes in geodynamic setting. They occur mostly in assemblages of the prehnite-pumpellyite facies filling amygdules and inside plagioclase phenocrysts.
(a) Pumpellyites from the three geodynamic settings define three distinct compositional fields in AFM space: (i) those in the Diabasic Group plot closer to the Fe corner; (ii) those in the Ocoite Group plot closer to the Al corner; (iii) those in the Celica Formation/Casma group plot between, and partly overlapping, fields (i) and (ii).
(b) Pumpellyites in group (i) formed in T-MORB like, K-poor tholeiites (high Fe/Al), affected by ocean-floor metamorphism in an oceanic back-arc basin. Pumpellyites in group (ii) generated in K-rich, calc-alkaline (low Fe/Al) to shoshonitic metabasites affected by burial metamorphism in an ensialic, aborted, marginal basin with moderate attenuation of the continental crust. Pumpellyites in group (iii) formed in basic and intermediate, calc-alkaline to tholeiitic rocks, metamorphosed in ensialic marginal basins with various degrees of continental crust thinning, from splitting to moderate attenuation. A correlation between pumpellyite and host-rock composition is suggested by these characteristics.
(c) Pumpellyites in prehnite-pumpellyite facies assemblages of some of the units studied plot inside higher (and lower) grade reference fields (AFM space) corresponding to different geodynamic settings elsewhere. This anomaly is attributed to the changing characteristics of the marginal basins at the South American margin and emphasizes the need to compare equal facies referred to equal settings. 相似文献
(a) Pumpellyites from the three geodynamic settings define three distinct compositional fields in AFM space: (i) those in the Diabasic Group plot closer to the Fe corner; (ii) those in the Ocoite Group plot closer to the Al corner; (iii) those in the Celica Formation/Casma group plot between, and partly overlapping, fields (i) and (ii).
(b) Pumpellyites in group (i) formed in T-MORB like, K-poor tholeiites (high Fe/Al), affected by ocean-floor metamorphism in an oceanic back-arc basin. Pumpellyites in group (ii) generated in K-rich, calc-alkaline (low Fe/Al) to shoshonitic metabasites affected by burial metamorphism in an ensialic, aborted, marginal basin with moderate attenuation of the continental crust. Pumpellyites in group (iii) formed in basic and intermediate, calc-alkaline to tholeiitic rocks, metamorphosed in ensialic marginal basins with various degrees of continental crust thinning, from splitting to moderate attenuation. A correlation between pumpellyite and host-rock composition is suggested by these characteristics.
(c) Pumpellyites in prehnite-pumpellyite facies assemblages of some of the units studied plot inside higher (and lower) grade reference fields (AFM space) corresponding to different geodynamic settings elsewhere. This anomaly is attributed to the changing characteristics of the marginal basins at the South American margin and emphasizes the need to compare equal facies referred to equal settings. 相似文献
13.
《Russian Geology and Geophysics》2007,48(1):91-106
We propose a model of the geodynamic evolution of the Dzhida island-arc system of the Paleoasian Ocean margin which records transformation of an oceanic basin into an accretion-collision orogenic belt. The system includes several Vendian-Paleozoic complexes that represent a mature oceanic island arc with an accretionary prism, oceanic islands, marginal and remnant seas, and Early Ordovician collisional granitoids. We have revealed a number of subunits (sedimentary sequences and igneous complexes) in the complexes and reconstructed their geodynamic settings. The tectonic evolution of the Dzhida island-arc system comprises five stages: (1) ocean opening (Late Riphean); (2) subduction and initiation of an island arc (Vendian-Early Cambrian); (3) subduction and development of a mature island arc (Middle-Late Cambrian); (4) accretion and formation of local collision zones and remnant basins (Early Ordovician-Devonian); and (5) postcollisional strike-slip faulting (Carboniferous-Permian). 相似文献
14.
V. B. Naumov V. I. Kovalenko V. A. Dorofeeva A. V. Girnis V. V. Yarmolyuk 《Geochemistry International》2010,48(12):1185-1207
We compiled a database containing more than 480000 determinations for 73 elements in melt inclusions in minerals and quenched
glasses of volcanic rocks. These data were used to estimate the mean contents of major, volatile, and trace elements in igneous
melts from main geodynamic settings. The following settings were distinguished: (I) oceanic spreading zones (mid-ocean ridges);
(II) zones of mantle plume activity on oceanic plates (oceanic islands and plateaus); (III) and (IV) settings related to subduction
processes, including (III) zones of island-arc magmatism generated on the oceanic crust and (IV) magmatic zones of active
continental margins involving the continental crust into magma generation processes; (V) intracontinental rifts and continental
hot spots; and (VI) back-arc spreading centers. The histogram of SiO2 contents in the natural igneous melts of all geodynamic settings exhibits a bimodal distribution with two maxima at SiO2 contents of 50–52 wt % and 72–74 wt %. The range 62–64 wt % SiO2 comprises the minimum number of determinations. Primitive mantle-normalized spidergrams were constructed for average contents
of elements in the igneous melts of basic, intermediate, and acidic compositions from settings I–V. The diagrams reflect the
characteristic features of melt compositions for each geodynamic setting. On the basis of the analysis of data on the composition
of melt inclusions and glasses of rocks, average ratios of incompatible trace and volatile components (H2O/Ce, K2O/Cl, Nb/U, Ba/Rb, Ce/Pb, etc.) were estimated for the igneous melts of all of the settings. Variations of these ratios were
determined, and it was shown that, in most cases, the ratios of incompatible elements are significantly different between
settings. The difference is especially pronounced for the ratios of elements with different degrees of incompatibility (e.g.,
Nb/Yb) and for some ratios with volatile components (e.g., K2O/H2O). 相似文献
15.
《International Geology Review》2012,54(6):714-736
We studied the geochemical characteristics of three types of Mesozoic igneous rocks from the Luzong volcanic basin: basaltic trachyandesite at Shuangmiao, pyroxene monzonite at Bajiatan, and quartz-syenite (A-type granite) at Huangmeijian. Based on analyses of whole-rock major elements, all investigated rocks are enriched in K, Na, Ti, Al, but depleted in Ca, representing a shoshonitic series. Trace element analyses show that these rocks are characterized by enrichments of large-ion lithophile elements and high field strength elements. Positive Nb and Ta anomalies in the chondrite-normalized spider diagram indicate that the shoshonitic volcanic rocks share similar features with Nb-enriched basalts, which are different from normal island-arc volcanical rocks (they are typically strongly depleted in Nb and Ta). Bulk-rock chemical compositions and Sr–Nd isotopes indicate that the three types of igneous rocks are geochemically comagmatic, suggesting that the melts were derived from an enriched mantle reservoir. We postulate an extensional tectonic setting for the formation of Luzong volcanic basin, possibly related to subduction of a palaeo-Pacific plate beneath the east Chinese continent during the Yanshanian period (Cretaceous). Therefore, the petrogenetic features of those volcanic rocks as well as A-type granites in the Luzong basin indicate that the regional large-scale Fe–Cu–Au mineralization was associated with oceanic slab melting, but not delamination or recycling of the ancient lower continental crust, as previously proposed. 相似文献
16.
In addition to ophiolites in the structure of the Otrozhnaya sheet, the igneous rocks were established within the Middle Devonian-Lower
Carboniferous tuffaceous-terrigenous complex earlier considered to be the cover of the ophiolite association. In order to
establish their geodynamic formation setting, the geochemical study of igneous rocks was conducted. The volcanic rocks from
the ophiolite complex are similar to MORB; subvolcanic rocks of tuffaceous-terrigenous complex have a suprasubduction origin.
An abundance of pyroclastic rocks and the type of sediments allow us to conclude about their formation in an island arc setting.
The existence of the Middle Devonian-Lower Carboniferous island arc complex within the Ust’-Belaya Mountains gives rise to
continue the Koni-Taigonos arc inside the region and testifies to its subsistence in the Devonian. 相似文献
17.
《International Geology Review》2012,54(5):788-802
The tectonics of Kamchatka are reviewed in some detail and in several cases reinterpreted in light of recent geological and geophysical studies. Maps present major structural features and magnetic data, obtained by aerial survey. Recent work has confirmed four young phases of tectogenesis, accompanied by intrusions: 1) Late Cretaceous to early Paleogene (Laramian or Kamchatka phase), 2) early Miocene (Kuril phase), 3) late Miocene (Aleutian phase), and 4) late Pliocene (Sakhalin phase). These account for the young folded region that covers most of the Kamchatka Peninsula and the Koryak uplands to the northeast. Three structural-stratigraphic zones are recognized. The west zone is a marginal trough filled with coal- and oil-bearing strata, moderately folded. The central zone is an inner volcanic arc made up of volcanic rocks cut by granitoid rocks. The east zone consists of thick flysch with basic and ultrabasic igneous rocks characteristic of external folded arcs. In general, major synclinoria and anticlinoria have northeast strikes, and magnetic values in general correlate with the strike and composition of these belts. The meridionally oriented Central Massif of ancient rocks controlled the development of structures in nearby Tertiary and Cretaceous rocks. Deep faults also trend northeast and determined the position of volcanic and metallogenic zones, the ophiolite belts, and the chain of intrusive massifs. Geophysical work shows that the northern part of the Sea of Okhotsk is of platform type; it has recently been postulated that the Okhotsk massif is part of the Siberian platform.—W.D. Lowry 相似文献
18.
安徽庐枞中生代火山岩系的特征及其形成的构造背景 总被引:15,自引:6,他引:15
庐枞地区中生代火山岩素是一套由粗面玄武岩-玄武粗安岩-粗安岩-粗面岩组成的岩石组合。岩石硅近饱和,全碱含量(尤其是K2O)高,K2O/Na2O、Fe2O3/FeO比值大,Al2O3含量高且变化大,TiO2含量低,富集Rb、Sr、Ba、Zr、Th、U和LREE等元素,稀土配分为轻稀土富集型,锶、铅、氧等同位素显示了岩浆的幔源特征。本文通过详细的岩石化学和地球化学的对比研究,认为庐枞中生代火山岩系属于橄榄玄粗岩系,它形成于活动大陆边缘由挤压作用向引张作用转变的过渡时期,是火山弧后拉张形成的前裂谷阶段的产物。 相似文献
19.
东北亚中生代火山岩研究若干问题的思考 总被引:14,自引:1,他引:13
东北亚中生代火山岩包括大陆边缘北北东向线型火山岩带,以及大陆内部俄罗斯西伯利亚、蒙古、中国大兴安岭等面型火山岩带。它们是东北亚古亚洲洋构造域向太平洋构造域转换时期深部地幔地球化学过程以及东亚大陆与古太平洋板块相互作用的产物。对它们的研究涉及古生代古亚洲构造域闭合过程的深部地幔的动力学和地球化学演化历史,以及东亚大陆边缘由被动边缘向活动大陆边缘转换历史。古亚洲域大洋岩石圈向地幔深部潜入而引发的热地幔 相似文献
20.
In the stratigraphic sequence of volcanic rocks in the Eastern Sikhote Alin, Maestrichtian-Danian predominantly andesitic volcanics are characterized by a boundary position between the Late Cretaceous subduction, mostly acid volcanic rocks and Cenozoic post-subduction basaltoids. Data on these rocks are important for elucidating the genesis of andesitic magmas, constraining and specifying the geodynamic evolutionary stages in this territory, and revealing the conditions under which the parental melts of these rocks were derived and evolved. Results of detailed mineralogical and geochemical studies, including ICP-MS analysis for trace elements point to a hybrid character of the andesitic volcanic rocks and an important role of fractional crystallization and crustal contamination in their genesis. Although geological evidence (variations in the style of volcanism, the composition of its products, and the character of their distribution) testifies to a change in the geodynamic environment in the Eastern Sikhote Alin in the Maestrichtian-Danian, geochemically the volcanics of this age range are typical subduction-related rocks with anomalously low concentrations of Nb and high contents of K, Ba, Rb, Pb, and U. The volcanic piles contain no adakites, which are indicators of the geodynamic environment in which slab windows are formed. The inconsistency between geological and geochemical indicators of the geodynamic environment suggests certain genetic features of the transitional magmatic series. The parental magmas of the andesitic volcanics were derived from the suprasubduction mantle wedge, which had been metasomatically recycled in the course of the dehydration and melting of the subducted oceanic slab. The increasing extension provided the possibility for the parental basaltic magmas to enter upper crustal levels, where they could interact with the host rocks and form hybrid andesitic melts. 相似文献