Petrology of postorogenic granitoids of the northern Baltic Shield     

V. R. Vetrin  N. G. Berezhnaya  N. V. Rodionov 《Doklady Earth Sciences》2006,411(9):1476-1479

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Origin of Pleistocene-Holocene ashes of the Russian northeast based on trace and rare earth element data     

V. G. Sakhno  L. I. Bazanova  O. Yu. Glushkova  I. V. Melekestsev  V. V. Ponomareva  A. A. Surnin  J. Olaf 《Doklady Earth Sciences》2006,411(9):1351-1356

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Variations in the electric field and turbulence in the surface atmospheric layer     

B. M. Koprov  S. V. Anisimov  V. M. Koprov 《Doklady Earth Sciences》2006,407(2):312-316

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Tidal wave period and seismicity     

V. A. Morgounov  E. A. Boyarsky  M. V. Stepanov 《Doklady Earth Sciences》2006,406(1):112-115

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Magmatism of the Hadean Geon in earth differentiation     

Yu. A. Balashov 《Doklady Earth Sciences》2006,409(6):875-878

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Mudstone lithogeochemistry and formation conditions of Vendian deposits in the Shkapovo-Shikhan Basin     

A. V. Maslov  M. V. Isherskaya  Yu. L. Ronkin  M. T. Krupenin  N. P. Gorbunova  T. Ya. Gulyaeva  O. P. Lepikhina  O. Yu. Popova  G. M. Yatluk 《Lithology and Mineral Resources》2006,41(3):250-270

Variation of geochemical modules and indices in mudstones from the Upper Vendian Kairovo and Shkapovo groups of the Shkapovo-Shikhan Basin provides the comprehensive information on changes in maturity of the fine aluminosiliciclastic material delivered in the basin, characterizes the redox environment in bottom water, and makes it possible to reconstruct the rock composition in provenance and its evolution through time. The generally moderate maturity of the fine terrigenous clastic material suggests that a nearly semiarid-semihumid climate dominated in paleodrainage area throughout the Late Vendian. It has been established that reducing environment did not exist in bottom water of the central Shkapovo-Shikhan Basin throughout the Late Vendian. Intermediate rocks prevailed in the paleodrainage area. More silicic rocks could occur only in the early Staropetrovo and late Salikhovo times. Data points of mudstones from the Kairovo and Shkapovo Groups plotted on the Cr-Ni, Co-V, Co/Hf-Ce/Cr, La-Th, and La/Sm-Sc/Th diagrams indicate that both Archean and more mature Paleoproterozoic crustal blocks existed in different proportions in the Late Vendian within source areas.  相似文献   

Tectonic evolution of the Caucasus and fore-Caucasus in the late paleozoic     

V. G. Kazmin 《Doklady Earth Sciences》2006,406(1):1-3

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Duration of migmatite formation in the granulite-facies metamorphism zone of Svecofennides of the Ladoga region, southeastern Baltic Shield     

Sh. K. Baltybaev  O. A. Levchenkov  V. A. Glebovitsky  L. K. Levskii  E. V. Kuz&#;mina  A. F. Makeev  S. Z. Yakovleva 《Doklady Earth Sciences》2006,407(2):271-274

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Upper Miocene, Pliocene, and Quaternary stratigraphic reference sections of large intermontane depressions in Armenia     

Yu. V. Sayadyan 《Doklady Earth Sciences》2006,407(2):217-219

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Mineralogy, geochemistry, and Nd isotope composition of the Rainbow hydrothermal field, Mid-Atlantic Ridge   总被引：3，自引：0，他引：3  

A. F. A. Marques  F. Barriga  V. Chavagnac  Y. Fouquet 《Mineralium Deposita》2006,41(1):52-67

Petrological, geochemical, and Nd isotopic analyses have been carried out on rock samples from the Rainbow vent field to assess the evolution of the hydrothermal system. The Rainbow vent field is an ultramafic-hosted hydrothermal system located on the Mid-Atlantic Ridge characterized by vigorous high-temperature venting (∼365°C) and unique chemical composition of fluids: high chlorinity, low pH and very high Fe, and rare earth element (REE) contents (Douville et al., Chemical Geology 184:37–48, 2002). Serpentinization has occurred under a low-temperature (<270°C) retrograde regime, later overprinted by a higher temperature sulfide mineralization event. Retrograde serpentinization reactions alone cannot reproduce the reported heat and specific chemical features of Rainbow hydrothermal fluids. The following units were identified within the deposit: (1) nonmineralized serpentinite, (2) mineralized serpentinite—stockwork, (3) steatite, (4) semimassive sulfides, and (5) massive sulfides, which include Cu-rich massive sulfides (up to 28wt% Cu) and Zn-rich massive sulfide chimneys (up to 5wt% Zn). Sulfide mineralization has produced significant changes in the sulfide-bearing rocks including enrichment in transition metals (Cu, Zn, Fe, and Co) and light REE, increase in the Co/Ni ratios comparable to those of mafic Cu-rich volcanic-hosted massive sulfide deposits and different ¹⁴³Nd/¹⁴⁴Nd isotope ratios. Vent fluid chemistry data are indicative of acidic, reducing, and high temperature conditions at the subseafloor reaction zone where fluids undergo phase separation most likely under subcritical conditions (boiling). An explanation for the high chlorinity is not straightforward unless mixing with high salinity brine or direct contribution from a magmatic Cl-rich aqueous fluid is considered. This study adds new data, which, combined with the current knowledge of the Rainbow vent field, brings compelling evidence for the presence, at depth, of a magmatic body, most likely gabbroic, which provides heat and metals to the system. Co/Ni ratios proved to be good tools used to discriminate between rock units, degree of sulfide mineralization, and positioning within the hydrothermal system. Deeper units have Co/Ni <1 and subsurface and surface units have Co/Ni >1.  相似文献