Pressure effect on forsterite dislocation slip systems: Implications for upper-mantle LPO and low viscosity zone

P. Raterron, J. Chen, T. Geenen, J. Girard

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

In order to better constrained the effect of pressure (P) on olivine dislocationslip-system activities, deformation experiments were carried out in a Deformation-DIA apparatus (D-DIA) on pure forsterite (Fo100) single crystals, at P ⩾ 5.7 GPa, temperature T ∼ 1675 K, differential stress σ <350 MPa and in water-poor conditions. Constant σ and specimen strain rates () were monitored in situ by synchrotron X-ray diffraction and radiography, respectively. Two compression directions were tested, promoting either [1 0 0] slip or [0 0 1] slip in (0 1 0) crystallographic plane. Comparison of the obtained high-P rheological data with room-P data previously reported by Darot and Gueguen (1981) shows that [1 0 0] slip is strongly inhibited by pressure while [0 0 1] slip is virtually P insensitive. This translates in creep power laws into a high activation volume for [1 0 0](0 1 0) slip system, and for [0 0 1](0 1 0) slip system. Using these laws along geotherms at natural σ condition shows that the [1 0 0] slip/[0 0 1] slip transition may occur at ∼200 km depth in the uppermantle, and be responsible for the observed lattice preferred orientation (LPO) transition. A rheological law for polycrystalline forsterite is deduced from the single-crystal rheological laws, assuming that individual grains are randomly oriented in the aggregate. Applying the aggregate law within a 2D geodynamic model of upper-mantle couette flow suggests that the pressure dependence of olivine dislocation-slip activities may partly explain the lowviscosityzone (LVZ) observed underneath oceanic plates
Original languageEnglish
Pages (from-to)26-36
Number of pages11
JournalPhysics of the Earth and Planetary Interiors
Volume188
Issue number1-2
DOIs
Publication statusPublished - 2011

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