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The effect of ductile deformation on the kinetics and mechanisms of the aragonite‐calcite transformation
Author(s) -
SNOW ELEANOUR,
YUND RICHARD A.
Publication year - 1987
Publication title -
journal of metamorphic geology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.639
H-Index - 114
eISSN - 1525-1314
pISSN - 0263-4929
DOI - 10.1111/j.1525-1314.1987.tb00376.x
Subject(s) - calcite , aragonite , nucleation , materials science , dislocation , creep , climb , deformation (meteorology) , dislocation creep , deformation mechanism , grain size , strain rate , mineralogy , geology , crystallography , grain boundary , metallurgy , composite material , microstructure , thermodynamics , chemistry , physics
The effect of ductile deformation (dislocation creep) on the kinetics of the aragonite‐calcite transformation has been studied at 1 atm (330° C and 360° C) and 900‐1500 MPa (500° C) using undeformed and either previously or simultaneously deformed samples (500° C and a strain rate of 10 ‐6 s). Deformation enhances the rate of the transformation of calcite to aragonite, but decreases the rate of transformation of aragonite to calcite. The difference results from a dependence of transformation rate on grain size, coupled with a difference in the accommodation mechanisms, climb versus recry‐stallization, of these minerals during dislocation creep. Dislocation climb is relatively easy in calcite and thus plastic strain results in high dislocation densities without significant grain size reduction. The rate of transformation to aragonite is enhanced primarily because of the increase in nucleation sites at dislocations and subgrain boundaries. In aragonite, on the other hand, dislocation climb is difficult and thus plastic strain produces extensive dynamic recry‐stallization resulting in a substantial grain size reduction. The transformation of aragonite is inhibited because the increase in calcite nucleation sites at dislocations and/or new grain boundaries is more than offset by the inability of calcite to grow across high angle grain boundaries. Thus the net effect of ductile deformation by dislocation creep on the kinetics of polymorphic phase transformations depends on the details of the accommodation mechanism.

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