Simulation of the Peritectic Phase Transition in Fe-C Alloys

In this work, a multi-phase cellular automaton (CA) model is extended for the quantitative simulation of peritectic phase transition. First, the effects of cooling rate/supersaturation and temperature on the peritectic transformation kinetics in Fe-C alloys are investigated by utilizing the present CA model. The CA simulations show that supersaturations in the parent phases (liquid and delta-ferrite) increase the L/gamma interface growth velocity remarkably, but tinily for the delta/gamma interface migration velocity. There exists a transition supersaturation for isothermal transformations, at which the growth rates of the two interfaces are equal. The transition supersaturation is found to increase with decreasing temperature. Microstructural evolution at different cooling rates during peritectic transformation is simulated using the experimental conditions. At low cooling rates, the delta/gamma interface propagates at a higher velocity than the L/gamma interface. At high cooling rates, however, the gamma-phase grows more into the L-phase with a cellular morphology. Then, the proposed CA model is applied to simulate the microstructural evolution during peritectic reaction. It is observed that the gamma-phase propagates along the L/delta interface and finally encircles the delta-phase. Meanwhile, the intervenient gamma-phase grows in thickness through peritectic transformation. The CA simulations are compared reasonably well with the experimental data and analytical calculations.

Automated summary

In this study, a multi-phase cellular automaton (CA) model is used to simulate the quantitative behavior of peritectic phase transition. The effects of cooling rate/supersaturation and temperature on the kinetics of peritectic transformation in Fe-C alloys are investigated. The results show that supersaturation in the parent phases significantly affects the growth velocity of the L/gamma interface. The proposed CA model is then applied to simulate the microstructural evolution during peritectic reaction.