Elevated-temperature Deformation Mechanisms in a CrMnFeCoNi High-Entropy Alloy

Stress reduction creep experiments were performed on a CrMnFeCoNi high-entropy alloy at 1073 K to characterize the steady-state and transient creep properties of this material. From measurements of constant-structure creep, the activation area for deformation of CrMnFeCoNi was determined to be similar to 100 b(2) and to decrease with increasing applied stress, indicating the presence of both concentrated solid so-lution and forest dislocation control of high temperature plastic deformation. With the aid of a recent solid solution theory for high entropy alloys, quantitative separation of the two mechanisms was carried out using a Haasen plot and the results show that creep in CrMnFeCoNi relies heavily on thermal activa-tion with the majority of creep strength coming from solid solution hardening, especially at low applied stresses. The overall analysis conducted in this study reveals that steady-state creep deformation of CrM-nFeCoNi at 1073 K can be adequately described by existing concentrated solid solution hardening models and forest dislocation hardening models. This observation suggests it may be possible to develop a unified treatment of the dislocation glide kinetics for this alloy from cryogenic to elevated temperatures. (C) 2021 The Author(s). Published by Elsevier Ltd on behalf of Acta Materialia Inc.

Automated summary

The stress reduction creep experiments on a CrMnFeCoNi high-entropy alloy at 1073 K revealed the dominant role of solid solution hardening mechanism in the creep behavior, with variations in behavior observed at different applied stresses. The study provides valuable insights for understanding the high temperature mechanical behavior of this alloy and suggests the potential for developing a unified treatment for dislocation glide kinetics across a range of temperatures.