Solute drag modeling for ferrite growth kinetics during precipitation experiments

Abstract

The growth kinetics of ferrite during intercritical annealing of steel has been investigated using in situ high energy X-ray diffraction with a specially designed furnace allowing highly quantitative measurements of phase volume fractions. Kinetics have been obtained at 730∘C, 750∘C and 775∘C in different ternary Fe-C-X (where X : Mn, Ni, Mo and Cr) alloys and in a quaternary Fe-C-1Mn-1Cr (wt.%) alloy. The obtained results were compared with the predictions of classical Local Equilibrium and Para-Equilibrium models as well as an improved version of a three-jump solute drag model, where the interactions between the solute elements and the moving interface are described comprehensively. Good agreement was obtained between the measured ferrite growth kinetics and the predictions of the solute drag model for the different Fe-C-X systems using only one fitting parameter, namely the Fe-X interaction parameter at the interface. The interactions found here qualitatively match those reported in literature for all solutes except for Ni, which displayed an attractive interaction with the interface. For the quaternary Fe-C-Mn-Cr system, the solute drag model succeeded in predicting ferrite growth kinetics using the same interaction values as used for the ternary Fe-C-Mn and Fe-C-Cr systems.