Late Paleozoic and Mesozoic deformations in the southwestern Primorye region     

V. P. Utkin  P. L. Nevolin  A. N. Mitrokhin 《Russian Journal of Pacific Geology》2007,1(4):307-323

Two types of tectonic deformations indicating different geodynamic settings are defined in the southwestern Primorye region. Near-latitudinal compression forces were responsible for the oldest, Late Paleozoic deformations. The Permian stratified complexes host a near-meridional system of folds and zones of dynamothermal metamorphism, cleavage, and foliation oriented orthogonally relative to the compression. Late Proterozoic (?) mafic-ultramafic rocks are characterized by similar deformations. In the Late Permian, the deformations were accompanied by granitoid magmatism controlled by fold and cleavage structures. The younger, Mesozoic deformations produced by near-meridional compression are represented by NE-trending sinistral strike-slip faults and their structural parageneses: an ENE-trending system of folds and downdip-thrusts both superimposed on Paleozoic protostructures and manifested in Mesozoic and Cenozoic sequences. It is inferred that, at the Paleozoic-Mesozoic boundary, near-latitudinal compression was replaced by near-meridional compression, probably, in response to the corresponding change in direction of the lateral displacement of the interacting Asian continent and (or) Pacific Plate.  相似文献   

The Tafuinsky granite massif,southern Primorye region: The structures and geodynamics of longitudinal compression     

P. L. Nevolin  V. P. Utkin  A. N. Mitrokhin 《Russian Journal of Pacific Geology》2010,4(4):331-346

Detailed observations and mass angular measurements in relicts of the host protoskeleton, their foliation, the shadow banding, the contacts between granite and aplite varieties, and taxitic texture served as the basis for the graphical and statistical analyses of the structural patterns in the Ordovician Tafuinsky granite intrusion. They revealed pre- and syn-granite types of structural patterns that were formed under the external longitudinal compression. The first of them is characteristic of the trajectories of structural elements constituting the protoskeleton hosting the massif and the shadow banding in the granites oriented transversely to the compression. The second type corresponds to the two main phases of the massif formation: the granite and the aplite. It is formed by combinations of conjugate counter-dipping thrusts and shears that control the distribution of the granite and aplite substances. In addition, these combinations frequently produce pseudofolded structures distinctly reflected in the control over the aplite bodies. Such a structural style of syngranite deformations suggests that, by their formation dynamics, they are similar to their pregranite counterparts. Both the pre- and syn-granite structural patterns demonstrate that the activation of the external compression was of different-order and pulsed mode with a certain periodicity. Moreover, the long compression pulses distinctly correspond to the stages and phases in the massif formation, when the compression twice changed its orientation at their transitions in the clockwise manner with an angular step of 10°. The geodynamics of the main longitudinal compression and its structural derivatives are regarded as a principal factor that determined the position and architecture of the massif.  相似文献   

The origin of basic rocks of the Korosten AMCG complex, Ukrainian shield: Implication of Nd and Sr isotope data     

Leonid Shumlyanskyy  Rob M. Ellam  Olexander Mitrokhin   《Lithos》2006,90(3-4):214-222

The Korosten complex is a Paleoproterozoic gabbro–anorthosite–rapakivi granite intrusion which was emplaced over a protracted time interval — 1800–1737 Ma. The complex occupies an area of about 12 000 km² in the north-western region of the Ukrainian shield. About 18% of this area is occupied by various mafic rocks (gabbro, leucogabbro, anorthosite) that comprise five rock suites: early anorthositic A₁ (1800–1780 Ma), main anorthositic A₂ (1760 Ma), early gabbroic G₃ (between 1760 and 1758 Ma), late gabbroic G₄ (1758 Ma), and a suite of dykes D₅ (before 1737 Ma). In order to examine the relationships between the various intrusions and to assess possible magmatic sources, Nd and Sr isotopic composition in mafic whole-rock samples were measured. New Sr and Nd isotope measurements combined with literature data for the mafic rocks of the Korosten complex are consistent and enable construction of Rb–Sr and Sm–Nd isochronous regressions that yield the following ages: 1870 ± 310 Ma (Rb–Sr) and 1721 ± 90 Ma (Sm–Nd). These ages are in agreement with those obtained by the U–Pb method on zircons and indicate that both Rb–Sr and Sm–Nd systems have remained closed since the time of crystallisation. In detail, however, measurable differences in isotopic composition of the Korosten mafic rock depending on their suite affiliation were revealed. The oldest, A₁ rocks have lower Sr (⁸⁷Sr/⁸⁶Sr₍₁₇₆₀₎ = 0.70233–0.70288) and higher Nd (εNd₍₁₇₆₀₎ = 1.6–0.9) isotopic composition. The most widespread A₂ anorthosite and leucogabbro display higher Sr and lower Nd isotopic composition: ⁸⁷Sr/⁸⁶Sr₍₁₇₆₀₎ = 0.70362, εNd₍₁₇₆₀₎ varies from 0.2 to − 0.7. The G₃ gabbro–norite has slightly lower εNd₍₁₇₆₀₎ varying from − 0.7 to − 0.9. Finally, G₄ gabbroic rocks show relatively high initial ⁸⁷Sr/⁸⁶Sr (0.70334–0.70336) and the lowest Nd isotopic composition (εNd₍₁₇₆₀₎ varies from − 0.8 to − 1.4) of any of the mafic rocks of the Korosten complex studied to date. On the basis of Sr and Nd isotopic composition we conclude that Korosten initial melts may have inherited their Nd and Sr isotopic characteristics from the lower crust created during the 2.05–1.95 Ga Osnitsk orogeny and 2.0 Ga continental flood basalt event. Indeed, εNd₍₁₇₆₀₎ values in Osnitsk rocks vary from 0.0 to − 1.9 and from 0.2 to 3.4 in flood basalts. We suggest that these rocks being drawn into the upper mantle might melt and give rise to the Korosten initial melts. ⁸⁷Sr/⁸⁶Sr₍₁₇₆₀₎ values also support this interpretation. We suggest that the Sr and Nd isotopic data currently available on mafic rocks of the Korosten complex are consistent with an origin of its primary melts by partial melting of lower crustal material due to downthrusting of the lower crust into upper mantle forced by Paleoproterozoic amalgamation of Sarmatia and Fennoscandia.  相似文献   

Role of latitudinal compression in the formation of Paleozoic intrusive structures in the southern Primorye region in the Far East     

P. L. Nevolin  V. P. Utkin  A. N. Mitrokhin  S. A. Kasatkin 《Russian Journal of Pacific Geology》2013,7(2):107-123

The structural-geodynamic features of the Anna, Gaidamak, Dunai, Tinkan, and Tafuin gabbroid and granite intrusions are analyzed. They are recently considered as elements of the basite Sergeevka terrane, which was previously known as the Sergeevka metagabbroid inlier (or massif). At the same time, their outcrops mark the ENE-trending Tafuin anticlinorium, which, being conjugate and synchronous with the northerly adjacent Petrovka depression, was formed in the Mesozoic as a constituent of the long-living Sergeevka structure. Therefore, these intrusions are considered in this work along with Cretaceous massifs, which occur among Mesozoic sediments, as resulting from tectonic-magmatic pulses transforming the basic substrate. These pulses mark the Proterozoic-Early Paleozoic, Late Paleozoic, and Mesozoic geodynamic periods with each being characterized by particular directions of the lateral compression with the Late Paleozoic one being the most intense. The latter was responsible for the near-meridional elongation of the structures and the dominant directions of their elements: the layering, banding, taxitic textures, cleavage, and foliation. All of them were determined by the cleavage formation and thrusting (in form of counter thrusts) of the same direction. The intrusions exhibit shear-type pseudofolds, which are considered as produced by flattening and warping.  相似文献   

Paleomagnetic study of Cenozoic sediments from the Zaisan basin (SE Kazakhstan) and the Chuya depression (Siberian Altai): tectonic implications for central Asia     

J. C. Thomas  R. Lanza  A. Kazansky  V. Zykin  N. Semakov  D. Mitrokhin  D. Delvaux 《Tectonophysics》2002,351(1-2)

This paper presents new paleomagnetic results on Cenozoic rocks from northern central Asia. Eighteen sites were sampled in Pliocene to Miocene clays and sandy clays of the Zaisan basin (southeastern Kazakhstan) and 12 sites in the upper Oligocene to Pleistocene clays and sandstones of the Chuya depression (Siberian Altai).Thermal demagnetization of isothermal remanent magnetization (IRM) showed that hematite and magnetite are the main ferromagnetic minerals in the deposits of the Zaisan basin. Stepwise thermal demagnetization up to 640–660 °C isolated a characteristic (ChRM) component of either normal or reverse polarity at nine sites. At two other sites, the great circles convergence method yielded a definite direction. Measurements of the anisotropy of magnetic susceptibility showed that the hematite-bearing sediments preserved their depositional fabric. These results suggest a primary origin of the ChRM and were substantiated by positive fold and reversal tests. The mean paleomagnetic direction for the Zaisan basin (D=9°, I=59°, k=19, α₉₅=11°) is close to the expected direction derived from the APW path of Eurasia [J. Geophys. Res. 96 (1991) 4029] and shows that the basin did not rotated relative to stable Asia during the Tertiary.In the upper Pliocene–Pleistocene sandstones of the Chuya depression, a very stable ChRM carried by hematite was found. Its mean direction (D=9°, I=46°, k=25, α₉₅=7°) is characterized by declination close to the one excepted for early Quaternary, whereas inclination is lower. In the middle Miocene to lower Pliocene clays and sandstones, a stable ChRM of both normal and reverse polarities carried by magnetite was isolated. Its mean direction (D=332°, I=63°, k=31, α₉₅=4°) is deviated with respect to the reference direction and implies a Neogene, 39±8° counterclockwise rotation of the Chuya depression relative to stable Asia. These results and those from the literature suggest that the different amount of rotation found in the two basins is related to a sharp variation in their tectonic style, predominantly compressive in the Zaisan basin and transpressive in the Siberian Altai. At a larger scale, the pattern of vertical axis rotations deduced from paleomagnetic data in northern central Asia is consistent with the hypothesis of a large left-lateral shear zone running from the Pamirs to the Baikal. Heterogeneous rotations, however, indicate changes in style of faulting along the shear zone and local effect for the domains with the largest rotations.  相似文献   

Geologic structure of Western Primorye: Structuring dynamics     

P. L. Nevolin  V. P. Utkin  A. N. Mitrokhin  T. K. Kutub-Zade 《Russian Journal of Pacific Geology》2012,6(4):275-293

The first data are reported on the structuring dynamics of Western Primorye. The analysis of the structural parageneses of the least studied macro- and mesolevels of the arrangement of the geologic space allowed us to distinguish three sequentially superposed structural patterns (parageneses), each of which was formed by its own stress field during separate geodynamic periods: the Late Proterozoic-Early Paleozoic, the Middle-Late Paleozoic, and the Mesozoic-Cenozoic. During the first two episodes of geodynamic activation (Late Proterozoic-Early Paleozoic), the main compression axis was oriented longitudinally. The first episode was characterized by the formation of a thrust-fold structural pattern. The second episode resulted in the superposition of the meridional riftogenic structures and, respectively, in the pull-apart normal-fault segmentation of the crystalline basement into mainly longitudinal blocks, which partially coincide with the previously distinguished terranes. During the latitudinal compression and oblate deformation that predominanted during the Middle-Late Paleozoic geodynamic period, the down-thrown and uplifted blocks were transformed into depressions and arches, respectively. The depressions were filled with Paleozoic sediments, while the primary rocks in the arches experienced granitization with the formation of two granitic complexes that joined terranes. The granites are characterized by shadow and shear-type fold and pseudofolded forms. The Mesozoic-Cenozoic period governed by NNW compression is divided into the Triassic-Jurassic, Early Cretaceous, and Tertiary tectonic episodes. During the Triassic-Jurassic period, the ENE-trending narrow arches and depressions were formed by warping. The arches accumulated granitized rocks, while the depressions were compensated for by the Early-Late Triassic sedimentary-volcanogenic sediments. All these processes led to the formation of structural complexes that joined and overlapped older complexes of meridional blocks (terranes) across the strike. Two subsequent Mesozoic-Cenozoic episodes manifested themselves in the discrete formation of coal-bearing depressions due to the NNW compression and ENE extension of the warping products.  相似文献