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1.
Integrate statistical processing of more than 1000 isotope dates tracing the history of circum-Pacific magmatic ore systems and related mineral deposits in volcanoplutonic belts allows the following inferences: (1) magmatic ore systems (MOS) of volcanic arcs generate monoand polycyclic volcanoplutonic deposits (VPD) with notably different formation times (longevities); (2) the MOS chronology bears periodicity of events in the post-Paleozoic history of the Pacific continental margin; (3) the time series of magmatic ore systems from different circum-Pacific segments show quasi-periodic patterns but the respective metallogenic epochs within the same time intervals have different phases and amplitudes, especially over the past 30 Myr; (4) each mineral type of VPD has its own periodicity; (5) the periodicity in formation times of mono- and polycyclic VPD differs from that in the times of their origin. 相似文献
2.
The Uimen-Lebed’ volcanoplutonic terrane is located at the junction of the Gorny Altai, Gornaya Shoriya, and western Sayan structures and is part of the Devonian-Early Carbonaceous Salair-Altai volcanoplutonic belt. The volcanic facies of the terrane composes the contrasting Nyrnin-Sagan Group, which includes basalt-basaltic andesite and basalt-rhyolite associations. The plutonic facies makes up the multiplet Elekmonar Group, which includes two independent complexes: monzogabbro-monzodiorite-granodiorite-granite and granodiorite-granite-leucogranite. The volcanic and plutonic rocks are asymmetrically distributed: volcanic sequences fill inherited depressions in the eastern part of the terrane, whereas plutonic complexes are located in its western part at the fault system branching from the transregional Kuznetsk-Teletsk-Kurai fault zone. The basalts of the Nyrnin-Sagan Group show geochemical signatures of both suprasubduction and rift-related rocks. The evolution of basaltoid magmatism reflects the formation and development of a suprasubduction mantle wedge in the inner part of an active continental margin accompanied by the influence of an intraplate mantle source. The silicic volcanism was generated under lower crustal conditions (P > 10 kbar) at the expense of metabasic materials and was accompanied by the influx of potassium into the anatectic zones. The gabbroids of the Elekmonar Group show suprasubduction geochemical features and no signatures of rift-related structures. The composition of the Elekmonar granitoids indicates significantly shallower (compared with the silicic volcanics) depths of their generation. The Uimen-Lebed’ volcanoplutonic terrane in the northeastern part of Gorny Altai was formed in the inner part of an active continental margin of the Andean type. Its magmatic complexes were formed over a considerable time range, from the early Emsian, when the formation of the active continental margin began, to the end of the Eifelian or, more likely, the beginning of the Givetian stage. 相似文献
3.
This paper reports first isotope–geochemical data on the Early Devonian magmatic rocks of the Chanchar potassic mafic volcanoplutonic complex of the Sakmara zone of the South Urals. The incompatible element distribution and ratios indicate that the rocks of the volcanic, subvolcanic, and intrusive facies are comagmatic and were derived from a common source. The low HFSE concentrations relative to MORB and relatively low 87Sr/86Sr and high 143Nd/144Nd ratios suggest that primary melts were generated from a moderately depleted mantle. The LILE enrichment of the rocks indicates a flux of mantle fluid in the primary magma during its evolution. 相似文献
4.
T.V. Donskaya D.P. Gladkochub A.M. Mazukabzov B. De Waele S.L. Presnyakov 《Russian Geology and Geophysics》2012,53(1):22-36
The Kataev volcanoplutonic association has been recognized in western Transbaikalia. It unites the volcanosedimentary rocks of the Kataev Formation and associated granites localized within the lower plates of the Buteel-Nuur and Zagan metamorphic-core complexes. The rocks of the Kataev association are dynamometamorphosed to different degrees, which is due to the tectonic exposure of metamorphic-core complexes in the Early Cretaceous. The U-Pb zircon dating of the Kataev Formation rhyolites yielded an age of 226 ± 3 Ma. The U-Pb zircon age of the granites intruding the Kataev Formation rocks is 223.4 ± 5.0 Ma. The volcanics of the Kataev Formation belong to the subalkalic basalt-andesite-dacite-rhyolite series. The trachybasalts and trachyandesite-basalts of the Kataev Formation have geochemical characteristics of igneous rocks formed as a result of subduction, e.g., they show distinct negative Nb and Ti and positive Ba and Sr anomalies on multielemental patterns. The specific composition of mafic volcanics points to their formation through the melting of a mantle source resulted from the mixing of depleted mantle and subduction components. Trachyandesites have higher Th and U contents than basaltoids. They can result from the contamination of a mantle source, similar in composition to the Kataev Formation basaltoids, with crustal material. The felsic volcanics of the Kataev Formation and granites intruding them show nearly identical geochemical characteristics corresponding to both A-and I-type granites. These rocks might have formed through the melting of a moderately water-saturated magmatic source of diorite-tonalite composition at 742–833°C. We have established that the rocks of the Kataev volcanoplutonic association in western Transbaikalia and Northern Mongolia formed in the Late Triassic synchronously with the calc-alkaline granitoids of the Henteyn–Daurian batholith and the alkali granites and bimodal volcanic associations of the Kharitonovo and Tsagaan-Hurtey volcanoplutonic associations. The synchronous formation of volcanoplutonic associations of normal and high alkalinity agrees with the geodynamic setting of the Andean-type active continental margin existing in the area of present-day western Transbaikalia and Northern Mongolia in the Early Mesozoic. This setting was the result of the subduction of the Mongol-Okhotsk oceanic plate beneath the Siberian continent. 相似文献
5.
A. A. Sorokin A. P. Sorokin V. A. Ponomarchuk A. V. Travin O. V. Melnikova 《Stratigraphy and Geological Correlation》2009,17(6):645-658
This study presents geochronological data (40Ar/39Ar) obtained for Mesozoic volcanic rocks superimposed upon different-aged rocks from the eastern portion of the Argun superterrane.
The new data on their age corresponds to the two episodes of magmatic activity distinctly manifested within the East Asia
during the Mesozoic and proves the asynchronous development of the volcanic complexes, which make up the eastern and western
flanks of the Umlekan-Ogodzha volcanoplutonic belt. It is assumed that the Umlekan-Ogodzha belt is a near EW section of a
series of different-aged near NS-trending volcanoplutonic belts subparallel to the Pacific margin. 相似文献
6.
V. A. Maslov 《Geochemistry International》2011,49(9):849-867
This paper reports the first petrological and geochemical evidence for the Meso-Neoproterozoic metamorphic and metaintrusive rocks of the Shaw Mountain massif (Prince Charles Mountains, East Antarctica). It was shown that the orthogneisses (plagiogneisses) and metabasites of the massif were formed as constituents of a volcanoplutonic complex, which included a variety of igneous rocks of normal and subalkaline groups, from ultrabasic to silicic and was assigned to the volcanic tholeiite basalt-andesite-rhyolite, plutonic peridotite-gabbro, and late (?) calc-alkaline gabbro-diorite-plagiogranite associations. The distribution of major and compatible trace elements indicates the fractionation of the primary melts that produced the volcanoplutonic association of the Shaw massif. With respect to the distribution of REE and trace elements and some trace element ratios, the metabasic rocks of the Shaw massif correspond mainly to enriched and normal basalts of mid-ocean ridges, continental rifts, and ocean islands, which suggests a contribution from a plume mantle source. It was found that the region of the Shaw massif is a high-grade metamorphosed margin of the Fisher volcanoplutonic complex, a Mesoproterozoic structure of single geodynamic nature. This is supported by the spatial proximity of the Shaw and Fisher regions, the similar behaviors of most major elements and distribution patterns of trace elements and REE in comparable magmatic associations, and the similar ages of some plutonic associations. Based on the petrological and geochemical data, an alternative geotectonic model was proposed for this region. According to this model, the Fisher complex was formed in a setting of continental rifting coupled with the processes of mantle diapirism, which was subsequently changed by the compression stage. During rifting, the structure could experience significant opening accompanied by ultrabasic-basic tholeiitic magmatism with a significant contribution of mantle material. A subsequent inversion resulted in that the rift structure underwent considerable horizontal compression accompanied by calc-alkaline magmatism and the formation of narrow intracratonic fold zones. The cyclic character of rifting processes and superposition of young rift systems on older ones was also established in the Phanerozoic geotectonic history of the region of the Prince Charles Mountains. 相似文献
7.
The results of reinterpretation of the geophysical data obtained during the study of the central sector of the Kuril Island Arc (2005–2010) are reported. The new boundaries of the shallow bedding of the basement and its block uplifts of varied composition are defined within the previously discovered zone of tectonic stretching and destruction of the Vityaz submarine ridge and interarc trough. Interblock depressions filled with sedimentary and volcanogenic-sedimentary rocks are distinguished. Areas represented by volcanoplutonic complexes including basic and sialic series (up to granite) are distinguished within the unbroken basement of the Vityaz Ridge. Intrusions and volcanic edifices composed of basic rocks are registered on the whole area studied. The relationship between the formation of the destruction zone and the geodynamic processes in the mantle is illustrated by the map of the Moho relief and structural-density model of the Earth’s crust. 相似文献
8.
班公湖-怒江带、羌塘地块特提斯演化
与成矿地质背景 总被引:2,自引:1,他引:2
孟家屯岩组是山东省地矿局第九地质队张连峰等人1992年进行1∶50000新汶、放城幅区调时,在新泰市孟家屯一带发现的一套石英岩组合的表壳岩,并将其划归为泰山岩群的底部[1]。前人认为孟家屯岩组总体上发生了3期变质作用?:第一期区域变质作用,使孟家屯岩组泥质岩中出现了斜长石、蓝晶石、铁铝榴石,基性岩中出现斜长石、普通角闪石等新生矿物,变质作用达中级变质,岩石的形成温度为T=530~630℃,压力p=0.58~0.72GPa,属中压相系中的低角闪岩相;第二期区域变质作用为泰山岩群地层发生的退变质作用,形… 相似文献
9.
班公湖-怒江带、羌塘地块特提斯演化
与成矿地质背景 总被引:32,自引:2,他引:30
早古生代—泥盆纪,研究区沉积环境以陆棚碎屑岩相和碳酸盐台地相为主,代表冈瓦纳大陆北缘和特提斯南侧的被动大陆边缘。石炭纪—二叠纪,本区进入特提斯南、北缘弧盆系统演化阶段,龙木错-双湖带北部、金沙江带南部和冈底斯带分别在石炭纪、二叠纪形成岩浆弧。中生代是特提斯南缘弧盆演化阶段,SSZ型蛇绿岩形成岩浆熔离型铬、镍、铂族金属矿床和热液型金矿。班公湖-怒江带特提斯在中侏罗世至早白垩世向南、北两侧俯冲并形成岩浆弧,该岩浆弧是重要的成矿带,形成斑岩铜矿、矽卡岩型磁铁矿和热液型多金属矿床。北羌塘东段侏罗纪弧后前陆盆地有利于形成沉积型、沉积-热液改造型和热液型铁、铜、锑、金矿床。晚白垩世碰撞作用主要与热液型矿床有关,分布范围较大,也可能存在晚白垩世至新生代碰撞阶段的斑岩铜矿。 相似文献
10.
A. A. Vorontsov V. V. Yarmolyuk D. A. Lykhin S. I. Dril S. A. Tatarnikov G. P. Sandimirova 《Petrology》2007,15(1):35-57
The Northern Mongolia-Western Transbaikalia rift zone is the largest Mesozoic riftogenic structure in eastern Asia and extends for a distance of more than 1200 km. The zone consists of depressions and grabens, which were formed between 233 and 188 Ma and are filled with basaltic and basalt-comendite (bimodal) volcanic associations accompanied by numerous peralkaline granite massifs. Geochemical and isotope (Sr, Nd, and Pb) studies showed that mantle and crustal sources contributed to the formation of the magmatic rocks of the rift zone. The basalts were formed from incompatible element-enriched mantle sources. Geochemical and isotope-geochemical data suggest that the peralkaline salic rocks (comendites and peralkaline grantoids) and basalts are genetically related and were formed by the fractionation of a common parental magma. In addition, the magmatic associations contain peralkaline granites and comendites whose isotope signatures indicate their formation through the crustal contamination of derivatives of basaltic melts. The rift zone has arisen during the formation of the Mongolia-Transbaikalia zoned magmatic area in a complex geodynamic setting, combining collision in the Mongolia-Okhotsk suture with a mantle plume impact. The rift zone occupies the northern periphery of the area, being controlled by the Northern Mongolia-Transbaikalia fault system, which marks the boundaries (sutures) of large terranes in the lithosphere. Asthenospheric traps beneath suture boundaries served as pathways for the penetration of a mantle plume into the upper lithosphere, thus playing an important role in the localization of the riftogenic processes. 相似文献
11.
《Russian Geology and Geophysics》2014,55(3):323-334
The geologic position, development stages, age, and geochemical features of metasomatic and felsic igneous rocks along the southern edge of the Siberian craton are compared. The comparison shows that all the studied metasomatic rocks are confined to the faults feathering the main suture zone of the craton. From Biryusa zone in the southwest and farther northeast, from Primor’e zone to Davan shear zone and Katugino-Ayan zone in the Aldan area, the metasomatic rocks are of similar composition but show higher mineralization. The process begins with blastocataclasis (barren stage). During the second stage, ore-bearing (Nb, Zr, Hf, and REE) potassic solutions circulate along the blastocataclastic zones. They form metasomatic potassic rocks of the early alkaline stage, expressed in subalkaline granitization. The next (acid) stage is marked by the formation of greisens with Sn, Be, Th, U, and W mineralization. The igneous stage might precede or follow the metasomatism. At the time of ongoing tectonic movements, it produces rapakivi-like granites rich in the same elements. Also, a huge volcanoplutonic belt develops along the craton edge during this time. The geochemical features of its felsic volcanics are close to those of the metasomatic rocks and granites. The age of all these rocks is within 2.1-1.6 Ga. 相似文献
12.
接触热变质带的划分对变质岩变质过程的研究提供了有力的依据。基于京西羊屎沟地区地层中变质矿物组合及其空间分布情况,对该区的接触热变质带进行划分,并分析变质作用的形成阶段。由于燕山期房山岩浆岩体侵入,使围岩发生不同程度的接触热变质作用,形成各种特征变质矿物。在特定岩石类型中,特征变质矿物有规律的组合。采用偏光显微镜透射法和X射线衍射分析,分为透辉石-透闪石带、二云母带、红柱石白云母带和绢云母带,表明距离岩体由近至远,岩石变质程度由高到低呈分带现象。伴随着岩浆侵入不同阶段形成不同的特征变质矿物,将接触热变质作用分为5个渐进的阶段。 相似文献
13.
1IntroductionAuriferousquartzveinsarecommonintheFengyangandZhangbalingregionsofAnhuiProvinceandtheyconstitutetheRongdu ,Zhuding ,Dagongshan ,MaoshanandShangchenggolddepositsandalotofgoldperspectives .TheRb SrisochronagesofalterationmineralsfromtheRongduandDagongshangolddepositsare (10 9.0± 4 .4 )Maand (15 3.76± 11.2 )Ma ,respectively (Dongetal .,1995 ) .Thereisalargedifferenceinagebetweenthetwogolddeposits ,butitcanbeseenthatthegolddepositswereformedinLateJurassictoEarlyCretaceous .A… 相似文献
14.
15.
四川丹巴伟晶岩型白云母矿床是我国第二大白云母产地,但其研究程度很低,形成机理的研究停留在定性推断的水平上,本文拟从流体的角度来研究其形成机理。丹巴北部的布衣沟位于白云母矿区的中心地带,自西向东穿过混合岩化变质带→部分混合岩化变质带→夕石化变质带,分布有蒋家→下蒋家→水大→二道桥等伟晶岩矿脉,其流体包裹体的均一温度峰值依次降低,CO2-H2O包裹体的数量逐渐减少,盐度有增高的趋势。碳、氢、氧同位素示踪出成岩成矿流体主要由携带深源碳的岩浆热液、建造水及脱碳反应产生的CO2组成。从蒋家→下蒋家→水大→二道桥伟晶岩脉,流体中的CO2/CH4和CO2/N2呈降低。这些特征显示出成岩成矿流体的演化过程:携带深源碳的岩浆热液自春牛场穹隆体的深部向外迁移,在部分混合岩化带与脱碳反应产生的CO2混合,在夕石带与建造水混合而稀释。因此丹巴白云母矿床属于“岩浆 变质”混合成因。 相似文献
16.
四川大岩子铂-钯矿床(点)热液成矿的地球化学证据 总被引:4,自引:0,他引:4
大岩子铂-钯矿区的岩石有白云岩、辉石岩脉、辉绿岩脉,矿体赋存在构造蚀变破碎带中,以外接触带的白云岩一侧为主,次为内接触带的辉石岩,矿石类型有矿化白云岩和矿化辉石岩两种类型。通过对含矿白云岩、含矿辉石岩、断层泥及辉绿岩的地球化学特征研究,认为大岩子矿床先后经历超基性岩浆的侵入,即形成辉石岩脉;基性岩浆的侵入,即形成辉绿岩脉;富含Pt、Pd的岩浆期后热液活动,即形成以Pt、Pd为丰、富含As、Cu、Sb、Ag、Cd的热液矿床,其中Pt、Pd的富集成矿主要与热液活动有关。 相似文献
17.
A. V. Kudymov 《Russian Journal of Pacific Geology》2010,4(6):495-501
The study of tectonic sliding surfaces (hereafter, slickensides) and striae, as well as strike-slip echelons of quartz streaks,
in the Kiselevka fault zone made it possible to reconstruct four groups of stress fields with a wide age range (from the Paleocene
to Recent). The meridional compression and latitudinal extension of the earliest stress field promoted the left-lateral displacement
along the Kiselevka fault. The fault activation in that period was accompanied by the final-phase magmatite formation in the
East Sikhote-Alin volcanoplutonic belt. In contrast, the subsequent stress field of the sublatitudinal compression and submeridional
extension changed the fault kinematics to right-lateral strike-slip ones. The origin and development of the Udyl intermontane
depression is linked to these deformations. Upthrow deformations complicated the structure of the Udyl depression, whereas
normal fault deformations produced the depression of Lake Udyl and the bays along the left bank of the Amur River. 相似文献
18.
黄羊沟闪长玢岩岩体侵位于甜水海—喀喇昆仑地块上侏罗统红其拉甫组灰岩地层中,为了厘定其形成时代,揭示岩石成因以及构造背景,对黄羊沟闪长玢岩岩体进行了LA-ICP-MS锆石U-Pb年代学及全岩地球化学分析研究。岩石地球化学研究结果表明,该岩体锆石U-Pb年龄为(159.9±1.4) Ma,形成于碰撞后伸展环境,源区具幔源特征,有地壳物质同化混染参与,形成条件为低压、强氧化环境,经历中等分异作用。该岩体具低硅(w(SiO2)=56.11%~57.36%)、高钙(w(CaO)=4.29%~6.59%)、富碱(w(Na2O+K2O)=6.00%~7.96%)特征,属准铝质(A/NCK=0.79~0.95)岩石,且富集大离子亲石元素K、Rb、Ba、Th、U及亏损高场强元素Nb、Ta、Zr、Hf等,具微弱Eu负异常,δEu均值为0.97。通过区域岩浆活动对比研究,认为黄羊沟岩体与班—怒缝合带革吉地区的帕阿岩体I型花岗岩体具有很强的亲缘性,且与班—怒缝合带内的岩浆岩时限一致,表明甜水海地体南部的黄羊沟闪长玢岩是班—怒缝合带以北区域中、新特提斯洋向南俯冲的岩浆作用响应。 相似文献
19.
Complex mineralogical, geochemical, and geochronological studies of the gabbroids from the Dzhigdinskii Massif located in the western part of the Dzhugdzhur–Stanovoy Superterrane are performed. It is established that the age of the rocks from the Dzhigdinskii Massif is Middle Triassic (244 ± 5 Ma), rather than Early Archean, as was previously assumed. The age of the Dzhigdinskii Massif is close to the age of the formation of the other Triassic gabbroid massifs, such as the Amnunaktinskii (~240 Ma), Lukindinskii (~250 Ma), and Luchinskii (~248 Ma) in the southeastern environ of the North Asian Craton. One of the stages in the formation of the Selenga–Vitim volcanoplutonic belt falls in this period as well. This indicates that the Selenga–Vitim volcanoplutonic belt, along with the granitoids and volcanic rocks, is composed of ultrabasic–basic and basic massifs and that this belt is superposed on the structures of the Selenga–Stanovoy Superterrane, as well as on the western part of the Dzhugdzhur–Stanovoy Superterrane. The gabbro, gabbro–diorite, and series of gabbro and gabbro–diorite with high sodic alkalinity from the Dzhigdinskii Massif show obvious geochemical features of duality, including combination of intraplate and super-subduction origin. In this relation, we can assume that the origin of the gabbroids of the Dzhigdinskii Massif is related to the detachment of the oceanic lithosphere and its subduction into the mantle with the formation of an “asthenospheric window.” 相似文献