Abstract
The annealing behavior of nanostructured aluminum AA1050 prepared by cold rolling to an ultrahigh strain (εvM = 6.4) has been investigated using both transmission electron microscopy and electron backscatter diffraction techniques, paying particular attention to changes in microstructure and texture during recovery and their influence on subsequent recrystallization. It is found that coarsening of lamellar structures during recovery can occur via triple junction motion, and that this process can modify the proportion of different boundary types and texture components compared to those in the cold rolled material. Additionally, the heavily deformed material is characterized by different textures and different spatial arrangements of rolling texture components in the center and subsurface. It is found that changes in the misorientation distribution and texture during coarsening are greatly affected by the initial spatial distribution of crystallographic orientations. In particular, the reduction in the fraction of high angle boundaries observed during recovery is much more pronounced in the subsurface layers than in the center layer. The initial through-thickness heterogeneity is thus greatly enhanced during recovery, which leads to significant differences in recrystallized microstructure and texture in the different layers.
Highlights
Materials deformed to high strains are characterized by very small boundary spacings and typically contain large fractions of high angle boundaries (HABs), which can result in a modified annealing behavior compared to materials deformed to low strains
It is found that coarsening of lamellar structures during recovery can occur via triple junction motion, and that this process can modify the proportion of different boundary types and texture components compared to those in the cold rolled material
This has been demonstrated in our previous electron backscatter diffraction (EBSD) study of an AA1050 sample cold rolled to a von Mises strain of 6.4, which had different proportions and different spatial distributions of rolling texture components in the center and subsurface layers [3]
Summary
Materials deformed to high strains are characterized by very small boundary spacings and typically contain large fractions of high angle boundaries (HABs), which can result in a modified annealing behavior compared to materials deformed to low strains. It is found that coarsening of lamellar structures during recovery can occur via triple junction motion, and that this process can modify the proportion of different boundary types and texture components compared to those in the cold rolled material. The heavily deformed material is characterized by different textures and different spatial arrangements of rolling texture components in the center and subsurface.
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