摘要
Phase-field method can be used to describe the complicated morphologies of dendrite growth without explicitly tracking the complex phase boundaries. The influences of initial temperature and initial concentration on dendrite growth are investigated by using the phase-field model coupling concentration field equations. The calculated results indicate that the supersaturation, which is larger in lower initial temperature and lower concentration under isothermal condition, plays a very important role in microsegregation. It is found that the larger supersaturation causes higher degree microsegregation and faster dendrite growth, and the more serious side-branchs occur. The simulated results agree well with the solidification theory.
Phase-field method can be used to describe the complicated morphologies of dendrite growth without explicitly tracking the complex phase boundaries. The influences of initial temperature and initial concentration on dendrite growth are investigated by using the phase-field model coupling concentration field equations. The calculated results indicate that the supersaturation, which is larger in lower initial temperature and lower concentration under isothermal condition, plays a very important role in microsegregation. It is found that the larger supersaturation causes higher degree microsegregation and faster dendrite growth, and the more serious side-branchs occur. The simulated results agree well with the solidification theory.
