The undercooling (∆T) dependencies of the solidification pathways, microstructural evolution, and recalescence behaviors of undercooled Co-18.5at.%B eutectic alloys were systematically explored. Up to four possible solidification pathways were identified: (1) A lamellar eutectic structure consisting of the FCC-Co and Co3B phase forms, with extremely low ΔT; (2) The FCC-Co phase primarily forms, followed by the eutectic growth of the FCC-Co and Co2B phases when ΔT < 100 K; (3) As the ΔT increases further, the FCC-Co phase primarily forms, followed by the metastable Co23B6 phase with the trace of an FCC-Co and Co23B6 eutectic; (4) When the ΔT increases to 277 K, the FCC-Co phase primarily forms, followed by an FCC-Co and Co3B eutectic, which is similar in composition to the microstructure formed with low ΔT. The mechanisms of the microstructural evolution and the phase selection are interpreted on the basis of the composition segregation, the skewed coupled zone, the strain-induced transformation, and the solute trapping. Moreover, the prenucleation of the primary FCC-Co phase was also detected from an analysis of the different recalescence behaviors. The present work not only enriches our knowledge about the phase selection behavior in the undercooled Co-B system, but also provides us with guidance for controlling the microstructures and properties practically.
Keywords: Co–B system; phase selection; pseudoeutectic regions; recalescence degree; solidification pathway.