Interstitial high-entropy alloys: Interstitial atoms enable joint twinning and transformation induced plasticity in strong and ductile high-entropy alloys

High-entropy alloys (HEAs) consisting of multiple principle elements provide an avenue for realizing exceptional mechanical, physical and chemical properties.

In this project we pursue a novel strategy for designing a new class of HEAs incorporating the additional interstitial element carbon. This results in joint activation of twinning- and transformation-induced plasticity (TWIP and TRIP) by tuning the matrix phase’s instability in a metastable TRIP-assisted dual-phase HEA. Besides TWIP and TRIP, such alloys benefit from massive substitutional and interstitial solid solution strengthening as well as from the composite effect associated with its dual-phase structure. Nanosize particle formation and grain size reduction are also utilized. The new interstitial TWIP-TRIP-HEA thus unifies all metallic strengthening mechanisms in one material, leading to twice the tensile strength compared to a single-phase HEA with similar composition, yet, at identical ductility.

Supplementary

The alloy was homogenized at 1200 ^oC for 2 h and followed by water-quenching. The region where the APT tips were taken from is marked in the EBSD pattern in Fig. 1a. (a) Three-dimensional APT tip reconstructions of atom positions in a typical tip. (b) Statistical binomial frequency distribution analysis results showing that the binomial curves obtained from experiments match the curves corresponding to a total random distribution. Several parameters were used to assess the quality of the fit, as listed in the inserted table. n_d and μ are the number of degrees of freedom for a given ion and normalized homogenization parameter, respectively. The values of μ for all elements are close to 0, confirming the random distribution of elements in the coarse-grained interstitial TWIP-TRIP-HEA.