Achieving high strength and ductility in nitrogen-doped refractory high-entropy alloys

Refractory high-entropy alloys (HEAs) usually exhibit high strength but limited ductility. Here, we report high strength (-1334 MPa) and large ductility (-18.8%) in nitrogen-doped TiZrNbTa HEAs. The microstructural evolution and the corresponding mechanical properties of the as-cast/annealed nitrogen-doped HEAs were investigated. All as-cast (TiZrNbTa)100-xNx (x = 0, 0.3, 0.6) HEAs exhibit a single-phase body-centred cubic structure. Interstitial strengthening contributes to the enhanced strength. The improved ductility of the 0.6 at.% nitrogen-doped HEA originates from the promoted planar dislocation slip inside grains. Spinodal decomposition and grain boundary (Zr, N)-enriched precipitates emerge when the nitrogen content is 0.9 at.%, which results in significant embrittlement. Isothermal annealing of the 0.6 at.% nitrogen-doped HEA at 800 degrees C to 1200 degrees C was conducted to further improve the mechanical performance. The complicated precipitates and grain boundary impurity segregation in the alloys annealed at 800 degrees C and 1200 degrees C lead to deteriorated strength and ductility. However, in the alloy annealed at 1000 degrees C, a slight increase in both strength and ductility appears due to solid solution strengthening, in situ grain refinement and promoted dislocation cross slip, which is induced by the coherent boundaries. This work provides a promising conduit to approach high strength and ductility in HEAs. (c) 2021 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY license (http:// creativecommons.org/licenses/by/4.0/).

Automated summary

Refractory high-entropy alloys (HEAs) doped with nitrogen show high strength and ductility properties. The optimal performance is achieved with 0.6% nitrogen doping. Isothermal annealing at different temperatures affects the mechanical properties of the alloys, with slight improvements in both strength and ductility observed at 1000°C due to various strengthening mechanisms.