Kinematics, nature of deformation and tectonic setting of the Taxaquara Shear Zone, a major transpressional zone of the Ribeira Belt (SE Brazil)

In this paper we have investigated the Taxaquara Shear Zone (TSZ), a major strike-slip structure within the Ribeira Belt (RB, SE Brazil) in order to assess its kinematics, the nature of deformation of rocks affected by the TSZ and its tectonic setting. The TSZ presents a vertical NE-trending mylonit...

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Published in:Tectonophysics 2019-01, Vol.751, p.83-108
Main Authors: Ribeiro, B.V., Faleiros, F.M., Campanha, G.A.C., Lagoeiro, L., Weinberg, R.F., Hunter, N.J.R.
Format: Article
Language:English
Subjects:
Biotite
Deformation
Deformation mechanisms
Dislocations
Feldspars
Grain boundaries
Grain boundary migration
Kinematics
Magma
Magnetite
Mica
Microphysical analyses
Muscovite
Orogeny
Quartz
Quartz and feldspar CPO
Ribeira belt
Rock
Rocks
Rutile
Shear zone
Shear zones
Slip
Solifluction
Strain rate
Tectonics
Thermodynamic modelling
Thermometers
Transpression
Twinning
Vorticity
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Summary:In this paper we have investigated the Taxaquara Shear Zone (TSZ), a major strike-slip structure within the Ribeira Belt (RB, SE Brazil) in order to assess its kinematics, the nature of deformation of rocks affected by the TSZ and its tectonic setting. The TSZ presents a vertical NE-trending mylonitic foliation and ENE- to WSW stretching lineation with variable plunge. Granitic rocks are intensely deformed giving rise to mylonites with newformed matrix assemblage (quartz + oligoclase + K-feldspar + biotite + muscovite + rutile + magnetite). This assemblage within a pseudosection couple with muscovite-biotite thermometer helps to constrain a metamorphic condition during deformation which spans ~513–525 °C and ~3.9–4.4 kbar with mean peak at ~520 °C and ~4.0 kbar. Quartz accommodates deformation through dislocation creep achieving subgrain rotation with minor contribution of grain boundary migration at a mean strain rate of 10−13–10−12 s−1. Feldspar porphyroclasts record brittle deformation (microfaults) and evidences of dislocation creep (e.g., kink twinning). The CPOs for monomineralic quartz ribbons display monoclinic pattern and activation of ‘basal- ’ + ‘rhomb- ’ slip systems during deformation. However, the CPOs for quartz and feldspar from fine-grained polyphase matrix show a switch in deformation mechanism from dislocation creep to diffusion creep. The vorticity and three-dimensional finite strain data results suggest that the TSZ was developed under a moderate to high strain conditions and a transpressional sub-simple shear environment, with predominance of simple over pure shear. Regional correlation with other structures from the Ribeira Belt and African Belts based on finite strain quantification support that a major transpressional system was mainly responsible for the shear zones development during late stages of Braziliano-Pan African orogeny. •Quantitative microstructural data from Taxaquara Shear zone are presented•The TSZ operated at ~520 °C and ~4 kbar with regular velocity (10−13–10−12 s−1)•Deformation was primarily accommodated by subgrain rotation of quartz aggregates•Feldspar deformed by dynamic recrystallization and granular flow•Field and structural quantitative data suggest sub-simple shear dominated transpression•Regional correlation between Ribeira and African belts supports transpression model
ISSN:0040-1951
1879-3266
DOI:10.1016/j.tecto.2018.12.025