Morphological Heredity of Intermetallic Nb5Si3 Dendrites in Hypereutectic Nb-Si Based Alloys via Non-Equilibrium Solidification

For hypereutectic Nb-Si based alloys, primary Nb5Si3 phases typically grow in a faceted mode during equilibrium or near-equilibrium solidification, which damages the ductility and toughness. To address this issue, here we artificially manipulate the growth morphology of Nb5Si3 using electron beam surface melting (EBSM) and subsequent annealing treatments. Results show that such a non-equilibrium solidification pathway enables the transition from faceted growth to non-faceted dendritic growth of Nb5Si3, along with evident microstructure refinement, generation of metastable beta-Nb5Si3 phases and elimination of chemical segregation. The transformation from beta-Nb5Si3 to alpha-Nb5Si3 and Nb solid solution (Nbss) particles is triggered by the annealing treatment at 1450 degrees C for 5 h. Also, we find the annealing-mediated formation of inherited Nb5Si3 dendrites that maintain the dendritic morphology of the original as-solidified beta-Nb5Si3 dendrites. This work thus provides a feasible routine to obtain thermally stable and refined alpha-Nb5Si3 dendrites in hypereutectic Nb-Si based alloys.