Thermodynamic and kinetic aspects on the selective surface oxidation of binary, ternary and quarternary model alloys

Abstract

Segregation and selective oxidation phenomena of minor alloying elements during annealing of steel sheets lead to the formation of bare spots after hot dip galvanizing. In order to understand the influence of common alloying elements on the surface chemistry after annealing, model alloys of binary (Fe–2Si, Fe–2Mn and Fe–0.8Cr), ternary (Fe–2Mn–2Si, Fe–2Mn–0.8Cr and Fe–2Si–0.8Cr) and quarternary (Fe–2Mn–2Si–0.8Cr) systems were investigated. The specimens were annealed for 60s at 820°C in N2–5% H2 gas atmospheres with different dew points −80 and −40°C, respectively. Surface chemistry of the annealed specimens was obtained by using X-ray photoelectron spectroscopy (XPS). The field emission scanning electron microscopy (FE-SEM) was used to view surface morphology. At low dew point −80°C, apart from the thermodynamical calculations such as solubility product of oxides and their critical solute concentrations, kinetics play a decisive role on the selective oxidation, i.e. oxygen competition. As expected, the amount of external selective oxidation of alloying elements are well pronounced at higher dew point −40°C. An attempt has been made to explain the dominant process of Si and Mn on Cr-oxidation and segregation. It is observed that annealing of quarternary system at higher dew point shifts the Cr-oxidation from external to internal.