Multi-stage phase transformation pathways in MAX phases

Diverse, multi-stage phase transformations occur in many materials under extreme environments. In response to irradiation, some MAX phase compositions transform from an initial hexagonal structure to an intermediate gamma-phase, then to a face-centered cubic (fcc) structure, while others instead become amorphous. To date, no comprehensive description of the associated transformation mechanisms, or of the influence of composition on this phase behavior, has been reported. In this work, we combine in situ ion irradiation, Transmission electron microscopy (TEM), and density-functional theory (DFT) calculations to demonstrate the distinct transformation pathways and corresponding energetics of the gamma-to-fcc transformation in a series of MAX phases. We show that structural distortion and bond covalency of the intermediate gamma-phase determine the outcome of the transformation process. This yields a generalized rule to predict the phase transition behaviors of MAX phases based on their atomic radii and electronegativity. These results provide an insight into the multi-stage phase transformation pathways along which MAX phase systems and related complex materials evolve in extreme environments.