Quantitative assessment of the influence of the Portevin-Le Chatelier effect on the flow stress in precipitation hardening AlMgScZr alloys

Portevin-Le Chatelier (PLC) effect often occurs in many alloy systems and leads to flow stress variations. When precipitation occurs, the PLC behavior changes and its resultant influence on the flow stress becomes more complicated, which has not yet been clarified. The well-known interaction mechanisms between precipitates and dislocations are shearing (shearable precipitates) and bypassing (non-shearable precipitates). This study systematically investigates the influence of the PLC effect on the flow stress in three cases, namely, without precipitates, with shearable precipitates, and with non-shearable precipitates. This study is performed on a AlMgZrSc alloy, where the precipitation does not change the concentration of solute species that is responsible for PLC. A modified constitutive relationship considering different dislocation-precipitate interactions is proposed, which can quantify the contribution of the PLC effect to the flow stress in the above three cases. The modeling results agree well with those of experiments performed on AlMg and AlMgScZr alloys exhibiting the PLC effect. It is theoretically demonstrated that PLC-induced strengthening can account for as much as 14.5% of the total flow stress in AlMg alloys. When shearable and non-shearable precipitates appear, this percentage decreases to approximately 4.5% and 9.5%, respectively, indicating that the precipitates weaken PLC-induced strengthening. Moreover, shearable precipitates can shorten the strain rate range of PLC, which is more effective in suppressing the PLC effect than non-shearable precipitates. Finally, the intrinsic mechanism responsible for the PLC-induced strengthening and roles of different precipitate-dislocation interactions are discussed.

Automated summary

The Portevin-Le Chatelier (PLC) effect is a common phenomenon in many alloy systems that leads to variations in flow stress. The influence of precipitation on PLC behavior and flow stress has not yet been fully understood. This study investigates the influence of the PLC effect on flow stress in three cases: without precipitates, with shearable precipitates, and with non-shearable precipitates. A modified constitutive relationship is proposed to quantify the contribution of the PLC effect in these cases. The modeling results are in good agreement with experiments on AlMg and AlMgScZr alloys, showing that PLC-induced strengthening can account for up to 14.5% of the total flow stress in AlMg alloys.