Nucleation behavior during solidification of cast iron at high undercooling

Abstract

During the solidification, of cast iron, a modest melt undercooling is a common observation, but the identity of the nucleation catalyst limiting the amount of undercooling has been elusive. In order to examine the influence of primary phases on the heterogeneous nucleation behavior of secondary phases in both hypoeutectic and hypereutectic cast irons, solidification catalysis experiments were carried out with differential thermal analysis (DTA) and droplet samples. To prevent decarburization and desiliconizaiton a SiO 2-Al 2O 3-CaO slag containing a droplet dispersion has been developed for cast irons. With the droplet sizes of less than 100 μm, large maximum undercoolings below the liquidus of 200–620 °C were obtained in both hypoeutectic and hypereutectic alloys. The maximum undercooling level (ΔT max/T L) reached up to 0.40 for a Fe-2.85wt.%C-1.91wt.%Si alloy. The undercooling for heterogeneous nucleation of secondary phases below the stable eutectic extended up to 430 °C for hypoeutectic alloys. The undercooling for a hypereutectic alloy was 20 °C. Based on the undercooling results, for hypoeutectic alloys the primary austenite iron (γ-Fe) is a poor nucleant for both graphite and cementite (Fe 3C). For hypereutectic alloys, primary graphite is very catalytic for γ-Fe. These results were examined by a lattice disregistry model and relative interfacial energy between nucleating solid and catalyst with respect to liquid. At large undercoolings, a variety of solidification microstructures have been observed.