Microstructural evolution and mechanical behavior of copper processed by low strain amplitude multi-directional forging

“…Figure a,b shows that a significant material work hardening occurs at the initial MDF stages for Δ ε = 0.15 and 0.30, resulting in flow stresses >4× above the yield strength ( σ y ) of the annealed material. The overall shape of the cumulative SS curves in Figure c is very similar for all strain amplitudes and typical of deformation conditions dominated by dynamic recovery . Work hardening is followed by an almost stationary flow stress achieved at ε ≈ 2.0, 2.1, and 2.4 for Δ ε = 0.075, 0.15, and 0.30, respectively.…”

“…The overall shape of the cumulative SS curves in Figure c is very similar for all strain amplitudes and typical of deformation conditions dominated by dynamic recovery . Work hardening is followed by an almost stationary flow stress achieved at ε ≈ 2.0, 2.1, and 2.4 for Δ ε = 0.075, 0.15, and 0.30, respectively. It should be noted that the saturation stress increases as the strain amplitude is raised, reaching ≈360 MPa for MDF 0.075 , ≈380 MPa for MDF 0.15 , and ≈390 MPa for MDF 0.30 .…”

“…The latter likely correspond to highly strained regions that underwent profuse micro shear banding during deformation . It should be further noted that the area fraction of these dark regions increases with increasing ε and Δ ε ; for MDF 0.075 , this fraction is ≈53% after ε = 10.8, for MDF 0.15 it evolves from ≈30% ( ε = 0.9) to 58% ( ε = 10.8), and for MDF 0.30 the evolution is from ≈39% to 70% considering the same accumulated strains.…”

“…It is evident in Figure a,b the occurrence of a rapid stress rise at the end of each compression due to the confining action of the die walls. These stress increments were not considered while constructing the cumulative flow stress curves as they cannot be attributed solely to the mechanical behavior of the material . For comparison purposes, the cumulative SS curves obtained in this study are plotted in Figure c together with the cumulative SS curve obtained for the same metal after 48 MDF cycles using Δ ε = 0.075 …”

“…Plots of a) grain size ( D ) and b) fraction of submicrometric grains ( f D≤1 ) as a function of ε and Δ ε for copper after MDF 0.075 , MDF 0.15 , and MDF 0.30 .…”

Influence of Strain Amplitude on the Microstructural Evolution and Flow Properties of Copper Processed by Multidirectional Forging

“…Figure a,b shows that a significant material work hardening occurs at the initial MDF stages for Δ ε = 0.15 and 0.30, resulting in flow stresses >4× above the yield strength ( σ y ) of the annealed material. The overall shape of the cumulative SS curves in Figure c is very similar for all strain amplitudes and typical of deformation conditions dominated by dynamic recovery . Work hardening is followed by an almost stationary flow stress achieved at ε ≈ 2.0, 2.1, and 2.4 for Δ ε = 0.075, 0.15, and 0.30, respectively.…”

“…The overall shape of the cumulative SS curves in Figure c is very similar for all strain amplitudes and typical of deformation conditions dominated by dynamic recovery . Work hardening is followed by an almost stationary flow stress achieved at ε ≈ 2.0, 2.1, and 2.4 for Δ ε = 0.075, 0.15, and 0.30, respectively. It should be noted that the saturation stress increases as the strain amplitude is raised, reaching ≈360 MPa for MDF 0.075 , ≈380 MPa for MDF 0.15 , and ≈390 MPa for MDF 0.30 .…”

“…The latter likely correspond to highly strained regions that underwent profuse micro shear banding during deformation . It should be further noted that the area fraction of these dark regions increases with increasing ε and Δ ε ; for MDF 0.075 , this fraction is ≈53% after ε = 10.8, for MDF 0.15 it evolves from ≈30% ( ε = 0.9) to 58% ( ε = 10.8), and for MDF 0.30 the evolution is from ≈39% to 70% considering the same accumulated strains.…”

“…It is evident in Figure a,b the occurrence of a rapid stress rise at the end of each compression due to the confining action of the die walls. These stress increments were not considered while constructing the cumulative flow stress curves as they cannot be attributed solely to the mechanical behavior of the material . For comparison purposes, the cumulative SS curves obtained in this study are plotted in Figure c together with the cumulative SS curve obtained for the same metal after 48 MDF cycles using Δ ε = 0.075 …”

“…Plots of a) grain size ( D ) and b) fraction of submicrometric grains ( f D≤1 ) as a function of ε and Δ ε for copper after MDF 0.075 , MDF 0.15 , and MDF 0.30 .…”

Influence of Strain Amplitude on the Microstructural Evolution and Flow Properties of Copper Processed by Multidirectional Forging

Faceting of Twin Grain Boundaries in High‐Purity Copper Subjected to High Pressure Torsion

Microstructural and Mechanical Evaluation of Pure Copper Rods Processed by Severe Plastic Deformation Method of Hydrostatic Cyclic Extrusion Compression