Unusual deformation-induced martensitic transformation in Fe-Co-Ni- Cr-Mn high entropy alloy thin films

Deformation-induced martensitic transformation in Fe-Co-Ni-Cr-Mn high entropy alloy (HEA) thin film with nanocolumnar growth feature are revealed to readily occur at intermediate deposition power rather than low and high deposition power ranges. The high probability of deformation-induced martensitic transformation from face-centered cubic (FCC) to hexagonal close-packed (HCP) phase in 150 W-film results in low nanoindentation hardness and compressive yield strength, in comparison with 60 W-and 210 W -films. Dependence of the martensitic transformation probability has been explained in terms of the com-petition between grain size effect and nanocolumn cohesion effect on the phase metastability. The in-creased grain size with deposition power favors the mechanical instability of FCC parent phase caused by the weakened slip obstruction, while the enhanced nanocolumn cohesion with deposition power hinders the formation of HCP martensite due to the increased activation energy for martensitic transformation. The grain size effect is dominated over the cohesion between nanocolumn at low deposition power range, while column cohesion effect is dominant at high deposition power range, which gives rise to the crossover of FCC-to-HCP with deposition power. This work might provide a deeper understanding in phase metastability of sputtered films, for instance, the effect of deposition power on deformation-induced martensitic trans-formation.(c) 2022 Published by Elsevier B.V.

Automated summary

Deformation-induced martensitic transformation in Fe-Co-Ni-Cr-Mn high entropy alloy thin films is influenced by the grain size and nanocolumn cohesion effect. The probability of martensitic transformation from face-centered cubic (FCC) to hexagonal close-packed (HCP) phase is higher in the 150 W film compared to the films deposited at 60 W and 210 W, resulting in lower nanoindentation hardness and compressive yield strength.