Discrimination of annealed and dynamic fabrics: Consequences for strain localization and deformation episodes of large-scale shear zones

Kinematic analysis of flow is becoming a well-established methodology, increasingly applied for its capability to contribute to the solution of complex topics in structural geology and tectonics, such as shear zones deforming by general shear.Vorticity evaluations based on stable porphyroclasts method have been used for many years to deduce large-scale tectonics of shear zones with different kinematics (Fossen & Cavalcante, 2017). However, limitations occur because a complex three dimensional problem, the motion of rigid clasts in a flowing matrix, is reduced to its two-dimensional analysis on the XZ plane of the finite strain ellipsoid (Iacopini et al., 2011; Mancktelow, 2013). Therefore vorticity estimates are limited by the extrapolation to three dimensions of two-dimensional data.We propose a totally new 3D approach based on the use of X-ray micro-computed tomography (X-ray micro-CT) that reflects the real 3D geometry and orientation of the porphyroclasts population. X-ray micro-CT allows to face the loss of dimensionality information imaging the rock sample in three dimensions and produces stacks of 2D grey-scale value images, called &#8220;slices&#8221;, that combined in 3D allow observing the internal structure of the scanned sample.We tested this approach chiefly on mylonitic orthogneiss from an intensively studied crustal scale shear zone: the Main Central Thrust zone (MCTz) of the Himalaya orogenic belt. Mylonites samples from other regional-scale shear zones in the Alps have been also used for comparison.The first and foremost consideration is that the use of micro-CT certainly increases the number of investigated clasts because hand samples are scanned: all clasts are evaluated. Micro-CT minimizes the problems due to the isolation factor, as it becomes possible to only select the clasts that do not interact with each other. Moreover, observation in three dimensions allows a more realistic evaluation of the aspect ratios and radii of clasts, avoiding erroneous measurements that generate systematic errors in the vorticity evaluation.We would like to stress that using the microCT we are able to evaluate all the clasts in the sample, avoiding those which do not meet the prerequisites of the method, otherwise not possible using classical 2D thin section based analysis.&#160;Fossen H. & Cavalcante G.C.G., 2017. Earth-Sci. Rev., 171, 434&#8211;455.Iacopini D. et alii, 2011. GSL Spec. Publ., 360, 301&#8211;318.Mancktelow N.S., 2013. J. Struct. Geol.,&#160;46, 235-254.Montemagni C. et alii, 2020. Terra Nova, 32, 215-224.

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PHYLLOSILICATES DISTRIBUTION, SPATIAL ARRANGEMENT AND INTERCONNECTIVITY: IMPLICATIONS FOR RHEOLOGICAL WEAKENING AND STRAIN LOCALIZATION IN DETACHMENT SHEAR ZONES (RAFT RIVER MOUNTAINS, UT)

10.1130/abs/2020am-356487 ◽

2020 ◽

Author(s):

Kristen Morris ◽

◽

Raphael Gottardi ◽

Gabriele Casale

Keyword(s):

Strain Localization ◽

Shear Zones ◽

Spatial Arrangement

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Rheological Contrast between Quartz and Coesite Generates Strain Localization in Deeply Subducted Continental Crust

Minerals ◽

10.3390/min11080842 ◽

2021 ◽

Vol 11 (8) ◽

pp. 842

Author(s):

Kouhei Asano ◽

Katsuyoshi Michibayashi ◽

Tomohiro Takebayashi

Keyword(s):

Rheological Behavior ◽

Strain Localization ◽

Shear Zones ◽

Ultrahigh Pressure ◽

Ultramafic Rocks ◽

Crustal Material ◽

Orientation Data ◽

Crystallographic Preferred Orientation ◽

Dabie Shan ◽

Felsic Rocks

Deformation microstructures of peak metamorphic conditions in ultrahigh-pressure (UHP) metamorphic rocks constrain the rheological behavior of deeply subducted crustal material within a subduction channel. However, studies of such rocks are limited by the overprinting effects of retrograde metamorphism during exhumation. Here, we present the deformation microstructures and crystallographic-preferred orientation data of minerals in UHP rocks from the Dabie–Shan to study the rheological behavior of deeply subducted continental material under UHP conditions. The studied samples preserve deformation microstructures that formed under UHP conditions and can be distinguished into two types: high-strain mafic–ultramafic samples (eclogite and garnet-clinopyroxenite) and low-strain felsic samples (jadeite quartzite). This distinction suggests that felsic rocks are less strained than mafic–ultramafic rocks under UHP conditions. We argue that the phase transition from quartz to coesite in the felsic rocks may explain the microstructural differences between the studied mafic–ultramafic and felsic rock samples. The presence of coesite, which has a higher strength than quartz, may result in an increase in the bulk strength of felsic rocks, leading to strain localization in nearby mafic–ultramafic rocks. The formation of shear zones associated with strain localization under HP/UHP conditions can induce the detachment of subducted crustal material from subducting lithosphere, which is a prerequisite for the exhumation of UHP rocks. These findings suggest that coesite has an important influence on the rheological behavior of crustal material that is subducted to coesite-stable depths.

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Effective rheology of a two-phase subduction shear zone: insights from numerical simple shear experiments and implications for subduction zone interfaces

10.5194/egusphere-egu21-10396 ◽

2021 ◽

Author(s):

Paraskevi Io Ioannidi ◽

Laetitia Le Pourhiet ◽

Philippe Agard ◽

Samuel Angiboust ◽

Onno Oncken

Keyword(s):

Simple Shear ◽

Large Scale ◽

Confining Pressure ◽

Shear Zones ◽

Dislocation Creep ◽

Small Scale ◽

Two Phase ◽

Weak Phase ◽

Pure Phases ◽

Geodynamic Models

Exhumed subduction shear zones often exhibit block-in-matrix structures comprising strong clasts within a weak matrix (m&#233;langes). Inspired by such observations, we create synthetic models with different proportions of strong clasts and compare them to natural m&#233;lange outcrops. We use 2D Finite Element visco-plastic numerical simulations in simple shear kinematic conditions and we determine the effective rheology of a m&#233;lange with basaltic blocks embedded within a wet quartzitic matrix. Our models and their structures are scale-independent; this allows for upscaling published field geometries to km-scale models, compatible with large-scale far-field observations. By varying confining pressure, temperature and strain rate we evaluate effective rheological estimates for a natural subduction interface. Deformation and strain localization are affected by the block-in-matrix ratio. In models where both materials deform viscously, the effective dislocation creep parameters (A, n, and Q) vary between the values of the strong and the weak phase. Approaching the frictional-viscous transition, the m&#233;lange bulk rheology is effectively viscous creep but in the small scale parts of the blocks are frictional, leading to higher stresses. This results in an effective value of the stress exponent, n, greater than that of both pure phases, as well as an effective viscosity lower than the weak phase. Our effective rheology parameters may be used in large scale geodynamic models, as a proxy for a heterogeneous subduction interface, if an appropriate evolution law for the block concentration of a m&#233;lange is given.

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Large-Scale Shear Tests on Interface Shear Performance of Landfill Liner Systems

Geosynthetics in Civil and Environmental Engineering ◽

10.1007/978-3-540-69313-0_88 ◽

2009 ◽

pp. 473-478

Author(s):

M. Kamon ◽

S. Mariappan ◽

T. Katsumi ◽

T. Inui ◽

T. Akai

Keyword(s):

Large Scale ◽

Shear Tests ◽

Interface Shear ◽

Landfill Liner ◽

Shear Performance ◽

Scale Shear

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Looking beyond kinematics: 3D thermo-mechanical modelling reveals the dynamic of transform margins

10.5194/se-2021-18 ◽

2021 ◽

Author(s):

Anthony Jourdon ◽

Charlie Kergaravat ◽

Guillaume Duclaux ◽

Caroline Huguen

Keyword(s):

Boundary Conditions ◽

Strain Localization ◽

Numerical Models ◽

Local Stress ◽

Shear Zones ◽

Strike Slip ◽

Convergent Margins ◽

Mechanical Modelling ◽

Kinematic Models ◽

Extension Direction

Abstract. Transform margins represent ~30 % of the non-convergent margins worldwide. Their formation and evolution have long been addressed through kinematic models that do not account for the mechanical behaviour of the lithosphere. In this study, we use high resolution 3D numerical thermo-mechanical modelling to simulate and investigate the evolution of the intra-continental strain localization under oblique extension. The obliquity is set through velocity boundary conditions that range from 15° (high obliquity) to 75° (low obliquity) every 15° for strong and weak lower continental crust rheologies. Numerical models show that the formation of localized strike-slip shear zones leading to transform continental margins always follows a thinning phase during which the lithosphere is thermally and mechanically weakened. For low (75°) to intermediate (45°) obliquity cases, the strike-slip faults are not parallel to the extension direction but form an angle of 20° to 40° with the plates' motion while for higher obliquities (30° to 15°) the strike-slip faults develop parallel to the extension direction. Numerical models also show that during the thinning of the lithosphere, the stress and strain re-orient while boundary conditions are kept constant. This evolution, due to the weakening of the lithosphere, leads to a strain localization process in three major phases: (1) strain initiates in a rigid plate where structures are sub-perpendicular to the extension direction; (2) distributed deformation with local stress field variations and formation of transtensional and strike-slip structures; (3) formation of highly localized plates boundaries stopping the intra-continental deformation. Our results call for a thorough re-evaluation of the kinematic approach to studying transform margins.

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