Jolien Linckens scite author profile

[1] The influence of second phases (e.g., pyroxenes) on olivine grain size was studied by quantitative microfabric analyses of samples of the Hilti massif mantle shear zone (Semail ophiolite, Oman). The microstructures range from porphyroclastic tectonites to ultramylonites, from outside to the center of the shear zone. Starting at conditions of ridge-related flow, they formed under continuous cooling leading to progressive strain localization. The dependence of the average olivine grain size on the second-phase content can be split into a second-phase controlled and a dynamic recrystallization-controlled field. In the former, the olivine grain size is related to the ratio between the second-phase grain size and volume fraction (Zener parameter). In the latter, dynamic recrystallization manifested by a balance between grain growth and grain size reduction processes yields a stable olivine grain size. In both fields the average olivine and second-phase grain size decreases with decreasing temperature. Combining the microstructural information with deformation mechanism maps suggests that the porphyroclastic tectonites (∼1100°C) and mylonites (∼800°C) formed under the predominance of dislocation creep. Since olivine-rich layers are intercalated with layer parallel, polymineralic bands in the mylonites, nearly equiviscous conditions can be assumed. In the ultramylonites, diffusion creep represents the major deformation mechanism in the polymineralic layers. It is this switch in deformation mechanism from dislocation creep to diffusion creep that forces strain to localize in the fine-grained polymineralic domains at low temperatures (<∼700°C), underlining the role of the second phases on strain localization in cooling mantle rocks.Citation: Linckens, J., M. Herwegh, O. Müntener, and I. Mercolli (2011), Evolution of a polymineralic mantle shear zone and the role of second phases in the localization of deformation,

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The role of second phases for controlling microstructural evolution in polymineralic rocks: A review

Herwegh

Linckens

Ebert

et al. 2011

Journal of Structural Geology

150

126

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Small quantity but large effect — How minor phases control strain localization in upper mantle shear zones

2015

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Dynamic recrystallization and phase mixing in experimentally deformed peridotite

Linckens

Bruijn

Skemer

2014

Earth and Planetary Science Letters

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Linking temperature estimates and microstructures in deformed polymineralic mantle rocks

Linckens

Herwegh

Müntener

2011

Geochem. Geophys. Geosyst.

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[1] To constrain deformation temperatures of mantle shear zones, we studied a strike-slip shear zone (Hilti massif, Semail ophiolite, Oman) and focused on the interaction between microstructural mechanisms and chemical equilibration processes. Quantitative microfabric analysis on harzburgites with different deformation intensity (porphyroclastic tectonite, mylonite, and ultramylonite) was combined with orthopyroxene geothermometry. The average grain size of all phases decreases with decreasing shear zone thickness. Dynamic recrystallization of porphyroclasts in combination with dissolution-precipitation and nucleation result in small-sized, chemically equilibrated pyroxenes. The composition of orthopyroxene was used to calculate deformation temperatures. In the case of the porphyroclastic tectonites, the chemical composition of orthopyroxene has been reset by diffusion yielding temperature estimates of 880-900°C. The mylonites were deformed by dislocation creep of olivine and show a broad range of calculated temperatures, which result from a combination of grain size reduction and inheritance of equilibrium compositions from earlier high-temperature events and diffusion. In mylonites, diffusion profiles combined with geothermometry and grain size analysis indicate a mylonitic deformation temperature of 800-900°C possibly followed by diffusion. In ultramylonites, the smallest grains (<30 mm) reveal equilibration at temperatures of ∼700°C during the last stages of ductile deformation, which was dominated by diffusion creep of olivine. Our results provide a crucial link between temperature and evolution of microstructures from dislocation creep to diffusion creep in mantle shear zones.

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Jolien Linckens

Evolution of a polymineralic mantle shear zone and the role of second phases in the localization of deformation

The role of second phases for controlling microstructural evolution in polymineralic rocks: A review

Small quantity but large effect — How minor phases control strain localization in upper mantle shear zones

Dynamic recrystallization and phase mixing in experimentally deformed peridotite

Linking temperature estimates and microstructures in deformed polymineralic mantle rocks

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