TY - JOUR
T1 - Mechanisms of electrically assisted deformation of an Al–Mg alloy (AA5083-H111): Portevin–Le Chatelier phenotype transformation, suppression, and prolonged necking
AU - Cerny, Angelika
AU - Grabner, Florian
AU - Arnoldt, Aurel R.
AU - Kunschert, Georg
AU - Mayr, Johann
AU - Zickler, Gregor A.
AU - Österreicher, Johannes A.
PY - 2024/9
Y1 - 2024/9
N2 - Aluminum-magnesium wrought alloys are well known for their advantageous properties and their application in various industries. However, the occurrence of the Portevin-Le Chatelier (PLC) effect leads to the formation of bands on the surface, thereby restricting the application of parts from Al-Mg alloys, primarily due to aesthetic concerns. Applying electrical pulses during deformation may not only improve the mechanical properties, moreover, it also affects the PLC effect. In this work, the properties of AA5083-H111 were investigated using standardized and electrically assisted tensile tests. Tensile behavior was assessed at room temperature, 250 degrees C, cryogenic conditions, and at two distinct electrically assisted conditions. We found that electrically assisted tensile testing leads to increased fracture strain compared to standard room temperature and cryogenic conditions. Furthermore, there was a transformation in PLC phenotypes, which included a partial suppression of the PLC effect. A spatio-temporal analysis of strain rate and strain highlights considerable differences in the occurrence of PLC bands and prolonged necking compared to standard room temperature testing. Furthermore, a modified dislocation pattern was observed using transmission electron microscopy.
AB - Aluminum-magnesium wrought alloys are well known for their advantageous properties and their application in various industries. However, the occurrence of the Portevin-Le Chatelier (PLC) effect leads to the formation of bands on the surface, thereby restricting the application of parts from Al-Mg alloys, primarily due to aesthetic concerns. Applying electrical pulses during deformation may not only improve the mechanical properties, moreover, it also affects the PLC effect. In this work, the properties of AA5083-H111 were investigated using standardized and electrically assisted tensile tests. Tensile behavior was assessed at room temperature, 250 degrees C, cryogenic conditions, and at two distinct electrically assisted conditions. We found that electrically assisted tensile testing leads to increased fracture strain compared to standard room temperature and cryogenic conditions. Furthermore, there was a transformation in PLC phenotypes, which included a partial suppression of the PLC effect. A spatio-temporal analysis of strain rate and strain highlights considerable differences in the occurrence of PLC bands and prolonged necking compared to standard room temperature testing. Furthermore, a modified dislocation pattern was observed using transmission electron microscopy.
KW - Aluminium
KW - Electroplastic Effect
KW - Kernel average misorientation
KW - Dislocation density
KW - spatio-temporal analysis
M3 - Article
SN - 0921-5093
VL - 910
JO - Materials Science and Engineering: A
JF - Materials Science and Engineering: A
M1 - 146865
ER -