Creep mechanisms in the lithospheric mantle ...
Document type :
Article dans une revue scientifique: Article original
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Title :
Creep mechanisms in the lithospheric mantle inferred from deformation of iron-free forsterite aggregates at 900–1200 °C
Author(s) :
Gasc, Julien [Auteur]
Demouchy, Sylvie [Auteur]
Barou, Fabrice [Auteur]
Koizumi, Sanae [Auteur]
Cordier, Patrick [Auteur]
Unité Matériaux et Transformations - UMR 8207 [UMET]
Demouchy, Sylvie [Auteur]
Barou, Fabrice [Auteur]
Koizumi, Sanae [Auteur]
Cordier, Patrick [Auteur]
Unité Matériaux et Transformations - UMR 8207 [UMET]
Journal title :
Tectonophysics
Abbreviated title :
Tectonophysics
Volume number :
761
Pages :
16-30
Publisher :
Elsevier BV
Publication date :
2019-06
ISSN :
0040-1951
English abstract : [en]
To further constrain the plasticity of rocks in the uppermost lithospheric mantle, deformation experiments were carried out on forsterite aggregates using a gas-medium apparatus (Paterson press) at 300 MPa, 900-1200 °C and ...
Show more >To further constrain the plasticity of rocks in the uppermost lithospheric mantle, deformation experiments were carried out on forsterite aggregates using a gas-medium apparatus (Paterson press) at 300 MPa, 900-1200 °C and nearly constant strain rates of ~ 10–5 s–1. The starting material is a synthetic iron-free forsterite aggregate with an average grain size of ~2.8 µm and ~2-3 % of iron-free enstatite. Eight deformation experiments were performed as well as an additional static annealing to characterize grain growth. The maximum stresses obtained range from ~480 to 1870 MPa. Below 1000 °C, where stress significantly exceeds confining pressure, and based on microstructural observations, grain boundary mediated creep is observed, with evidences of sliding and cavitation (gaping) at grain boundaries. At 1050-1200 °C, where pseudo-steady state could be achieved, the microstructures are very different and show evidences of dislocation activity, resulting from the activation of several dislocation slip systems with increasing temperature. When compared to rheology laws previously obtained from similar experiments, the temperature dependence of iron-free olivine creep is similar to the one of its iron-bearing counterpart at high temperature (∼1200 °C); at temperatures ≤1000 °C, however, the strength of iron-free olivine is higher than for iron-bearing olivine. The deformation-induced textures obtained show that grain boundary sliding (GBS) was leading to cavitation, which was likely activated in response to large differential stresses, i.e., beyond the Goetze criterion. Given these high-stress conditions, our results cannot be directly applied to deformation of the Earth’s mantle at large scale, but they highlight the key role played by the grain-boundary network in producing strain at lithospheric temperatures (< 1100 °C), when crystal-plastic mechanisms remain inefficient.Show less >
Show more >To further constrain the plasticity of rocks in the uppermost lithospheric mantle, deformation experiments were carried out on forsterite aggregates using a gas-medium apparatus (Paterson press) at 300 MPa, 900-1200 °C and nearly constant strain rates of ~ 10–5 s–1. The starting material is a synthetic iron-free forsterite aggregate with an average grain size of ~2.8 µm and ~2-3 % of iron-free enstatite. Eight deformation experiments were performed as well as an additional static annealing to characterize grain growth. The maximum stresses obtained range from ~480 to 1870 MPa. Below 1000 °C, where stress significantly exceeds confining pressure, and based on microstructural observations, grain boundary mediated creep is observed, with evidences of sliding and cavitation (gaping) at grain boundaries. At 1050-1200 °C, where pseudo-steady state could be achieved, the microstructures are very different and show evidences of dislocation activity, resulting from the activation of several dislocation slip systems with increasing temperature. When compared to rheology laws previously obtained from similar experiments, the temperature dependence of iron-free olivine creep is similar to the one of its iron-bearing counterpart at high temperature (∼1200 °C); at temperatures ≤1000 °C, however, the strength of iron-free olivine is higher than for iron-bearing olivine. The deformation-induced textures obtained show that grain boundary sliding (GBS) was leading to cavitation, which was likely activated in response to large differential stresses, i.e., beyond the Goetze criterion. Given these high-stress conditions, our results cannot be directly applied to deformation of the Earth’s mantle at large scale, but they highlight the key role played by the grain-boundary network in producing strain at lithospheric temperatures (< 1100 °C), when crystal-plastic mechanisms remain inefficient.Show less >
Audience :
Non spécifiée
Collections :
Research team(s) :
Plasticité
Submission date :
2019-05-23T07:55:10Z