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Deformations and Manifestations of Degassing in the Sedimentary Cover of the Equatorial Segment of the West Atlantic: Implications for Lithospheric Geodynamics

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Abstract

Manifestations of fluids and deformations in the sedimentary cover, which are both factors of brightening (blanking anomalies) in seismoacoustic records, in the equatorial segment of the Atlantic coincide with the sublatitudinal zones of the activated passive parts of transform faults and with zones of lower gravity anomalies and higher values of remnant magnetization, which form as a result of serpentinization. The cause-and-effect sequence of intraplate phenomena includes: the contrasting geodynamic state → horizontal movements that form macrofractures → water supply to the upper mantle → serpentinization of rocks in the upper mantle → deformations associated with vertical uplift of basement and sedimentary cover blocks, coupled with fluid generation → and fluid accumulation in the sedimentary cover, accompanied by the formation of anomalies in seismoacoustic records. Based on the seismic data, we have identified imbricate-thrust deformations, diapir structures, stamp folds, and positive and negative flower structures, indicating the presence of strike-slip faults in the passive parts of transform faults. The general spatial distribution of deformation structures shows their concentration in cold mantle zones. Correlative comparison of the structural characteristics of deformations shows the direct relationship between the heights of structures and the development of serpentinization processes. As per the age of the basement, deformations range from 27–38 to 43–53 Ma; a quite thick sedimentary cover makes it possible to reveal them based on the characteristic types of seismoacoustic records. The formation of the Antilles arc ca. 10 Ma ago affected the equatorial segment of the Atlantic; it formed kink bands where lithospheric blocks underwent displacements with counterclockwise rotations, deformations related to compression and vertical uplift of crustal fragments, and local extension that favored degassing of endogenous fluids. Sublatitudinally oriented imbricate-thrust deformations with different vergences indicate irregularity and alternating strike-slip directions as blocks between fractures were laterally influenced.

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Authors and Affiliations

  1. Geological Institute, Russian Academy of Sciences, Moscow, 119017, Russia

    S. Yu. Sokolov, A. O. Mazarovich, N. N. Turko, K. O. Dobrolyubova, A. S. Abramova, Yu. A. Zaraiskaya & E. A. Moroz

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  1. S. Yu. Sokolov
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  2. A. O. Mazarovich
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  3. N. N. Turko
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  4. K. O. Dobrolyubova
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  5. A. S. Abramova
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  6. Yu. A. Zaraiskaya
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  7. E. A. Moroz
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Correspondence to S. Yu. Sokolov.

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Original Russian Text © S.Yu. Sokolov, A.O. Mazarovich, N.N. Turko, K.O. Dobrolyubova, A.S. Abramova, Yu.A. Zaraiskaya, E.A. Moroz, 2018, published in Geotektonika, 2018, No. 4, pp. 3–24.

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Sokolov, S.Y., Mazarovich, A.O., Turko, N.N. et al. Deformations and Manifestations of Degassing in the Sedimentary Cover of the Equatorial Segment of the West Atlantic: Implications for Lithospheric Geodynamics. Geotecton. 52, 401–420 (2018). https://doi.org/10.1134/S0016852118040076

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