How Does Viscosity Contrast Influence Phase Mixing and Strain Localization?

Cross, Andrew; Olree, Elizabeth; Couvy, H.; Skemer, Philip

doi:10.1029/2020jb020323

Cited by 7 publications

(9 citation statements)

References 111 publications

(210 reference statements)

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“…In order to accurately model plate‐scale lithospheric deformation, we therefore need a comprehensive understanding of the microphysical processes that produce strain weakening across a broad range of conditions in rock‐forming minerals. Many studies have linked strain weakening at relatively low homologous temperatures (

{T}_{h}

<0.7) to mechanisms such as grain size evolution (Karato et al., 1986; Rutter, 1995), CPO development (Schmid et al., 1987; Urai et al., 1986), partial melting (Burlini & Bruhn, 2005; Hirth & Kohlstedt, 1995), metamorphic reactions and transformations (Gordon, 1971; Poirier, 1982), water weakening (Griggs & Blacic, 1965; Karato et al., 1986; Kronenberg & Tullis, 1984) and mineral phase mixing and/or layering (Bons & Cox, 1994; Cross et al., 2020). However, we lack a comprehensive understanding of the processes that produce strain weakening in rocks and minerals at very high temperatures (

{T}_{h}

>0.7).…”

Section: Discussionmentioning

confidence: 99%

Crystallographic Preferred Orientation (CPO) Development Governs Strain Weakening in Ice: Insights From High‐Temperature Deformation Experiments

et al. 2021

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{T}_{h}

{T}_{h}

>0.7).…”

Section: Discussionmentioning

confidence: 99%

Crystallographic Preferred Orientation (CPO) Development Governs Strain Weakening in Ice: Insights From High‐Temperature Deformation Experiments

et al. 2021

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“…Some entrained grains developed parallel to mylonitic foliation. These observations suggest that the compositional layers became severely attenuated and eventually disaggregated to form mixed aggregates [18]. To characterize each compositional layer, we used an EBSD map to select 20 subdomains (Figures 7b and 8; see also Figures S1 and S2 for all subdomains), for which we calculated the mineral modes of quartz and plagioclase, as well as their grain sizes and CPOs (Figures 9 and 10; see also Figures S3-S6 for all the subdomains).…”

Section: Microstructures and Crystallographic Preferred Orientations ...mentioning

confidence: 99%

“…As quartz-plagioclase phase mixing is likely in Figure 8 and Figure S2, we calculated the viscosity contrast as a function of stress, grain size, and temperature for the quartzplagioclase composites under wet conditions, as proposed by Cross et al [18] (Figure 11). The viscosities of the quartz-and plagioclase-rich layers were calculated using laboratoryderived flow laws for wet quartz [11,63,64] and wet plagioclase (Ab 100 ) ( [65] (Table 1).…”

Section: Viscosity Contrast Estimatementioning

confidence: 99%

“…However, there remains continued discussion over the precise mechanisms responsible for grain-scale phase mixing (e.g., [14][15][16][17]). More recently, Cross et al [18] has proposed that the ideal conditions for mechanical phase mixing under wet middle-to lower-crust conditions are 400-800 • C, 10-100 MPa stress, and 10-100 µm grain size, where the quartz-plagioclase viscosity contrast is minimized to <10. Here, we attempted to assess whether these conditions apply to natural rocks, such as ultramylonite, in a shear zone.…”

Section: Introductionmentioning

confidence: 99%

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Effect of Low Viscosity Contrast between Quartz and Plagioclase on Creep Behavior of the Mid-Crustal Shear Zone

Endo,

Michibayashi,

Okudaira

et al. 2024

Minerals

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Ultramylonites are among the most extreme fault rocks that commonly occur in the mid-crustal brittle–plastic transition and are mainly characterized by intensely sheared fine-grained microstructures and well-mixed mineral phases. Although the deformation mechanism of ultramylonites is key to understanding the rheological behavior of the mid-crustal shear zone, their microstructural development is still controversial owing to their intensely fine-grained textures. To investigate the possible crustal deformation mechanisms, we studied 13 mylonites obtained from the Kashio shear zone along the Median Tectonic Line that is the largest strike-slip fault in Japan. In particular, we investigated various mixed quartz–plagioclase layers developed within tonalitic mylonite, which are representative of the common mean grain size and crystal fabric of quartz among the studied samples. A high-quality phase-orientation map obtained by electron backscattered diffraction showed not only a wide range of quartz–plagioclase mixing (10%–80% in quartz modal composition) but also revealed a correlation between grain size reduction and crystal fabric weakening in quartz, indicating a change in the deformation mechanism from dislocation creep to grain-size-sensitive creep in the mixed quartz-plagioclase layers. In contrast, plagioclase showed an almost consistent fine grain size and weak to random crystal fabrics regardless of modal composition, indicating that grain size-sensitive creep is dominant. Combined with laboratory-determined flow laws, our results show that the Kashio shear zone could have developed under deformation mechanisms in which the viscosities of quartz and plagioclase are nearly comparable, effectively within 1017–1019 Pa·s, thereby possibly enabling extensive shearing along the Median Tectonic Line.

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“…Similar effects have been demonstrated theoretically (Bercovici et al., 2023; Bercovici & Mulyukova, 2021) and experimentally in samples composed of Ol + Opx (Tasaka et al., 2017, 2020), calcite + anhydrite (Cross & Skemer, 2017), and quartz + albite (Cross et al., 2017). Additionally, microstructural developments from experimentally deformed samples have been used to investigate possible mechanisms responsible for efficiently mixing two or more mineral phases in samples in which pinning is effective (Cross et al., 2020; Cross & Skemer, 2017; Tasaka et al., 2017). However, many of these experimental studies focused on two‐phase samples with only one to three different proportions of the two phases.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Secondary‐Phase Fraction on the Deformation of Olivine + Ferropericlase Aggregates: 1. Microstructural Evolution

2023

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To study the microstructural evolution of polymineralic rocks, we performed deformation experiments on two‐phase aggregates of olivine (Ol) + ferropericlase (Per) with periclase fractions (fPer) between 0.1 and 0.8. Additionally, single‐phase samples of both Ol and Per were deformed under the same experimental conditions to facilitate comparison of the microstructures in two‐phase and single‐phase materials. Each sample was deformed in torsion at T = 1523 K, P = 300 MPa at a constant strain rate up to a final shear strain of γ = 6 to 7. Microstructural developments, analyzed via electron backscatter diffraction (EBSD), indicate differences in both grain size and crystalline texture between single‐ and two‐phase samples. During deformation, grain size approximately doubled in our single‐phase samples of Ol and Per but remained unchanged or decreased in two‐phase samples. Zener‐pinning relationships fit to the mean grain sizes in each phase for samples with 0.1 ≤ fPer ≤ 0.5 and for those with 0.8 ≥ fPer ≥ 0.5 demonstrate that the grain size of the primary phase is controlled by phase‐boundary pinning. Crystallographic preferred orientations, determined for both phases from EBSD data, are significantly weaker in the two‐phase materials than in the single‐phase materials.

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How Does Viscosity Contrast Influence Phase Mixing and Strain Localization?

Cited by 7 publications

References 111 publications

Crystallographic Preferred Orientation (CPO) Development Governs Strain Weakening in Ice: Insights From High‐Temperature Deformation Experiments

Crystallographic Preferred Orientation (CPO) Development Governs Strain Weakening in Ice: Insights From High‐Temperature Deformation Experiments

Effect of Low Viscosity Contrast between Quartz and Plagioclase on Creep Behavior of the Mid-Crustal Shear Zone

The Effect of Secondary‐Phase Fraction on the Deformation of Olivine + Ferropericlase Aggregates: 1. Microstructural Evolution

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