Types of Size-Dependent Melting in Fe Nanoclusters: a Molecular Dynamics Study

Metallic nanoclusters are of interest in many fields because of their size-dependent catalytic activity. This activity can, in part, be influenced by their melting properties. In this work, the melting phase transitions of $Fe_{n}$ nanoclusters with $n \leq 100$ atoms were investigated using classical many-body molecular dynamics simulations. Adding a single atom to many cluster sizes induced strong variations in surface and core melting points, and cluster energetics. Clusters with size-dependent melting behavior were classified into 3 distinct cluster types: closed-shell, near-closed-shell, and far-from-closed-shell clusters. For small clusters, near-closed-shell clusters had very low surface melting points and very high melting points (heat capacity maximum). Cluster sizes with symmetric closed shells and near-closed shells almost always had first-order-like phase transitions. For intermediate cluster sizes, far-from-closed-shell clusters often exhibited second-order-like phase transitions due to geometric factors. Larger cluster sizes began to favor bcc lattice structures. Variations in the surface and core melting behavior of neighboring cluster sizes may have implications for catalytic systems such as the growth of single-wall carbon nanotubes.