Effects of isotherm patterns on cellular interface morphologies of melt pool origin

TL;DR

This study uses three-dimensional phase-field simulations to explore how different isotherm patterns influence cellular microstructures and segregation in solidifying melt pools, revealing significant effects of isotherm shape and tilt.

Contribution

It introduces the first 3D phase-field simulation approach to analyze the impact of isotherm patterns on cellular structures in melt pool solidification.

Findings

Non-planar isotherms produce finer cellular structures.

Tilted isotherms cause tilted cellular arrays.

Isotherm variations significantly affect microsegregation.

Abstract

Spatiotemporal variation of the thermal gradient in the melt pool inherited from different heat input patterns or other non-equilibrium transient effects during additive manufacturing can significantly affect the resulting subgrain microstructure evolution. To examine the impact of this variation, we approximate the thermal gradient by various isotherm patterns that move with constant velocity following directional solidification. We report the first three-dimensional phase-field simulations to investigate the effects of isotherm patterns on the cellular structures typically observed in solidified melt pools. Results indicate that small variations in the isotherm can considerably impact the microstructural features. We use appropriate statistical characterizations of the solid fraction, solid percolation, and solute partitioning behavior to demonstrate the influence of isotherm patterns on the dendritic structures and semisolid mushy zones. Consistent with experimental observations, we find that non-planar isotherms produce finer cells and reduced microsegregation compared to planar isotherms. Also, we note that a tilt of the isotherm leads to a tilted state of the resulting cellular arrays. Our findings will help in understanding the qualitative aspects of the influence of temperature gradient patterns on the evolution of solidification morphologies, mushy zones, and secondary phases, which are crucial for the macroscopic description of the solidified material.