Tracing intermediate phases during crystallization in a Ni-Zr metallic glass

Abstract Crystallization of metallic glasses (MGs) is a complex dynamic process, driven by thermodynamics and limited by kinetics, which often involves in the phase transformation from the metastable amorphous state, via intermediates, to final stable crystalline states. The intermediate structural state remains mysterious at present but very crucial to a deeper understanding of the physics and mechanisms of the crystallization process. Detailed structural characterization of the complicated intermediate crystalline phases using transmission electron microscopy (TEM) provides a unique platform to study such issues. Here, we monitor the evolution of the crystallization process for Ni65Zr35 (at.%) MG ribbon with structural heterogeneities. Direct visualization combined with compositional analysis reveal that the intermediate phase with Zr concentration higher than that of MG consists of the inter-stacked nanometer-sized layers of Ni-rich units (Ni at.% > 67 %) and Ni10Zr7-like units, where the thin Ni-rich single layer gradually disappears with increasing the annealing temperature. Our findings provide insight into the key role of Ni in the structural transition process, improving the understanding of the atomic diffusion-dominated crystallization in MGs.