3.9  ·  Competing Processes During Deformation  49
                 Fig. 3.35.
                 Pinning structure of quartz
                 grain boundaries on white mica.
                 Amphibolite facies micaceous
                 quartzite. Southern Minas Gerais,
                 Brazil. Width of view 2.5 mm. CPL















































                 Fig. 3.36. a Low magnification TEM image of equidimensional grains in quartz ultramylonite. Note occurrence of voids (marked V) at triple
                 points and grain boundary micas (marked M); b TEM image of free dislocations, visible as dark lines, inside small quartz grains from an
                 ultramylonite. The homogeneous distribution of recovered dislocations indicates that dislocation creep was a significant deformation mecha-
                 nism, but dominant grain boundary sliding is suggested by a random LPO in the quartz grains, measured by electron diffraction, and the
                 voids at the grain boundaries. Quartz ultramylonite, Portugal. (Photographs courtesy Martyn Drury)

                 of recovery, and finally to combined GBM and SGR recrys-  indirectly, on deformation parameters such as strain rate
                 tallisation because of increasing ease of diffusion in the crys-  and temperature. In general, a high temperature and the
                 tal lattice (Hirth and Tullis 1992). The same seems to apply  presence of a fluid on grain boundaries promotes recovery
                 to other minerals (Lafrance et al. 1996) but switches in ac-  and recrystallisation processes; high strain rate enhances
                 commodation mechanism will occur at other temperatures.  crystal distortion. These facts have been known from the
                   At high temperatures, diffusion processes may accom-  earliest age of metalworking; a sword or horseshoe can be
                 pany or take over from dislocation climb and recrystallisa-  shaped from a piece of metal by hammering if it is suffi-
                 tion (Sect. 3.8).                             ciently heated. In thin section, only structures related to the
                   The state of affairs during any stage of deformation and  last stages of the competing processes are normally pre-
                 the final result that we observe in deformed rocks depend  served, formed shortly before temperature and/or strain rate
                 on the relative importance of the processes listed above and,  fell below a critical value and the structures were ‘frozen in’.