Effect of high energy ball milling, heat treatment and spark plasma sintering on structure, composition, thermal stability and magnetism in CoCrFeNiGax (x = 0.5; 1) high entropy alloys
Н. Ф. Шкодич, Tatiana Smoliarova, Hasan Ali, Benedikt Eggert, Ziyuan Rao, M. Spasova, И. А. Тарасов, Heiko Wende, Katharina Ollefs, Baptiste Gault, Michael Farle
Abstract
Nanocrystalline (∼10 nm) singe- fcc CoCrFeNiGa x (x = 0.5, 1.0) high entropy alloy (HEA) particles with excellent structural and compositional homogeneity were prepared from elemental powders using single-step, short-term (190 min) high energy ball milling (HEBM) at room temperature (RT). Both HEA powders exhibit paramagnetic behaviour at RT with a small ferromagnetic contribution at low fields (saturation magnetization M s = 4.5 – 7.5 Am 2 /kg; average Curie temperature T c = 130 K – 150 K). They are thermally stable up to 1295 K–1305 K despite the low melting temperature of Ga (302.9 K). Heat treatment up to 1000 K enhances M s to 59.9 Am 2 /kg and T c to 740 K for the CoCrFeNiGa HEA powder due to an irreversible fcc → bcc structural transformation, whereas the magnetic properties of CoCrFeNiGa 0.5 do not show this enhancement. In-situ TEM heating reveals nanosized σ-phase Cr-rich precipitates (< 50 nm) at 875 K only for the CoCrFeNiGa HEA powder. Spark plasma sintering (SPS) of powders produces homogeneous nanocrystalline bulk HEAs. SPS at 1073 K of the CoCrFeNiGa 0.5 powder increased the crystallinity of the fcc phase. Three-dimensional local compositional mapping at atomic resolution by atom probe tomography indicates a homogeneous distribution of all elements. Bulk HEAs exhibit similar magnetic behavior as heat-treated HEA powders. Combining HEBM and SPS yields homogeneous bulk HEAs with low-melting Ga and enhanced structural, composition, and thermal stability, as well as improved magnetic properties ( M s = 55Am 2 /kg and T c = 750 K), which is 45% and 47 K higher, respectively, compared to conventional melting approaches.