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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

2024Acta Materialia22 citationsDOIOpen Access PDF

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.

Topics & Concepts

Spark plasma sinteringMaterials scienceBall millHigh entropy alloysThermal stabilityMetallurgyMagnetismSinteringPlasmaHigh energyThermalThermodynamicsCondensed matter physicsChemical engineeringAlloyEngineering physicsEngineeringQuantum mechanicsPhysicsHigh Entropy Alloys StudiesHigh-Temperature Coating BehaviorsAdditive Manufacturing Materials and Processes
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 | Litcius