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1 Yale University, Department of Geology & Geophysics
New Haven, CT
06520, USA
E-mail:
sun-ichiro.karato{at}yale.edu
2 Stony Brook University, Department of Geosciences
Stony Brook, NY 11794,
USA
E-mail:
dweidner{at}sunysb.edu
Most large-scale geological processes, such as mantle convection and
plate tectonics, involve plastic deformation of rocks. However, quantitative
experimental studies of plastic properties under deep-mantle conditions are
challenging, and major progress in this area has often been associated with
the development of new techniques. Until very recently, reliable studies have
been conducted only at pressures less than 
0.5 GPa (15 km depth in
Earth). By combining novel techniques of synchrotron-based in situ
stress-strain measurements with newly designed high-pressure apparatuses, a
new generation of experimental studies of plastic deformation of minerals
under deep-mantle conditions is emerging. These studies constrain the pressure
dependence of deformation of minerals such as olivine and the slip systems in
high-pressure minerals such as wadsleyite and perovskite. These results have
important implications for the depth variation of mantle viscosity and the
geodynamic interpretation of seismic anisotropy.
KEYWORDS: rheology, deep mantle, plastic deformation, seismic anisotropy, DDIA, RDA
This article has been cited by other articles:
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  J. D. Bass and J. B. Parise Deep Earth and Recent Developments in Mineral Physics Elements, June 1, 2008; 4(3): 157 - 163. [Abstract] [Full Text] [PDF]
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