4.7 Article

Microstructure stability during high temperature deformation of CoCrFeNiTa eutectic high entropy alloy through nano-scale precipitation

Publisher

ELSEVIER SCIENCE SA
DOI: 10.1016/j.msea.2021.141793

Keywords

Dual-phase microstructure; Eutectic high entropy alloys; Precipitation; High-temperature deformation; FEM simulation

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The study focused on the CALPHAD guided design of a hypo-eutectic high entropy alloy with a dual-phase microstructure, which exhibited excellent high-temperature mechanical properties. The addition of alloying elements and thermal effects led to the formation of multiple fine precipitates, extending the usable temperature range of the alloy. Under room temperature conditions, the alloy showed good mechanical performance and at high temperatures, there were various kinds of precipitates in the FCC solution phase.
Dual-phase microstructures arising out of eutectic reactions offer several advantages: ease of casting, composite properties and tunable characteristic length scale of the phases. Eutectic high entropy alloys (EHEA) with a multi-component solution phase and a hard intermetallic phase are candidate materials to identify alternate high-temperature materials. Alloying elements can be chosen to improve the resistance to lamellar microstructure degradation and coarsening. In this work, we present the CALPHAD guided design of a hypo-eutectic high entropy alloy CoCrFeNiTa0.395 with primary dendritic FCC phase and fine eutectic (FCC solution + Laves phase) microstructure possessing good high-temperature mechanical properties. The primary FCC phase fraction is 0.42 +/- 0.02. The interlamellar spacing of the eutectic is 0.69 +/- 0.12 mu m. The alloy exhibited a balanced yield strength of 1303 +/- 18 MPa, a fracture strength of 2237 +/- 23 MPa and a fracture strain of 0.3 under mom temperature compression testing. The mechanism for change in the lamellar morphology during deformation at temperatures beyond 0.8 T-E is explained schematically. Strain field distribution obtained by FEM simulation correlates well with the observed microstructure gradients in the deformed samples. The formation of nano-scale precipitates in the low strain rate deformation is attributed to thermal effects. High-temperature precipitation of two types of precipitates (L1(2) ordered and Ni3Ta type) in the FCC-solution phase extended the useable temperature range of this alloy.

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