Boron segregation at austenite grain boundaries: An equilibrium phenomenon

Abstract

High-resolution secondary ion mass spectrometry imaging, atom probe tomography and transmission electron microscopy have been employed to investigate boron segregation at austenite grain boundaries (γGB) in a high-strength steel. Boron content in solid solution, interfacial excess at γGB and precipitate number density were quantified after heat treatments specifically designed to promote non-equilibrium segregation of boron. The samples were first soaked at 1100°C, followed by rapid cooling to different isothermal holding temperatures, and then quenched to room temperature. We found that boron distribution does not evolve after holding at 460°C, even after bainitic transformation, suggesting a low mobility of boron at this temperature. In contrast, after holding at high temperatures (780°C and 820°C), boron distribution evolves remarkably: boron content in solid solution close to the interface and boron interfacial excess decrease similarly with the increase of holding time, while their ratio remains almost constant; at the same time, transient precipitation of M23(B,C)6 particles occurs at the grain boundaries. The experimental results on interfacial excesses at γGB and the solute profiles in the vicinity of the grain boundary agree with the results of a numerical model of coupled diffusion and equilibrium segregation phenomena. These results unambiguously exclude the hypothesis that non-equilibrium segregation controls the kinetics of boron segregation and confirm that boron segregation is only controlled by the equilibrium segregation mechanism.