Thermal stability and deformation mechanisms in Ni-Co-Fe-Cr-Al-Ti-Nb-type nanoparticle-strengthened high-entropy alloys

doi:10.1016/j.jmst.2023.05.044

Abstract

Abstract: The precipitate morphologies, coarsening kinetics, elemental partitioning behaviors, grain structures, and tensile properties were explored in detail for L1₂-strengthened Ni_39.9Co₂₀Fe₁₅Cr₁₅Al₆Ti_4-_xNb_xB_0.1 (x = 0 at.%, 2 at.%, and 4 at.%) high-entropy alloys (HEAs). By substituting Ti with Nb, the spheroidal-to-cuboidal precipitate morphological transition, increase in the coarsening kinetics, and phase decomposition upon aging at 800 °C occurred. The excessive addition of Nb brings about the grain boundary precipitation of an Nb-rich phase along with the phase decomposition from the L1₂ to lamellar-structured D0₁₉ phase upon the long-term aging duration. By partially substituting Ti with Nb, the chemically complex and thermally stable L1₂ phase with a composition of (Ni_58.8Co_9.8Fe_2.7)(Al_12.7Ti_5.8Nb_7.5Cr_2.3) ensures the stable phase structure and clean grain boundaries, which guarantees the superb high-temperature mechanical properties (791 ± 7 MPa for yielding and 1013 ± 11 MPa for failure) at 700 °C. Stacking faults (SFs) were observed to prevail during the plastic deformation, offering a high work-hardening capability at 700 °C. An anomalous rise in the yield strength at 800 °C was found, which could be ascribed to the multi-layered super-partial dislocations with a cross-slip configuration within the L1₂ particles.

Key words: High-entropy alloys, Coarsening kinetics, Coherent precipitation strengthening, Mechanical properties

J.X. Hou, J.Y. Zhang, J.X. Zhang, J.H. Luan, Y.X. Wang, B.X. Cao, Y.L. Zhao, Z.B. Jiao, X.J. Liu, W.W. Song, P.K. Liaw, T. Yang. Thermal stability and deformation mechanisms in Ni-Co-Fe-Cr-Al-Ti-Nb-type nanoparticle-strengthened high-entropy alloys[J]. J. Mater. Sci. Technol., 2023, 167: 171-183.

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