Effect of Carbon and Nitrogen on Md₃₀ in Metastable Austenitic Stainless Steel

Abstract

Md₃₀ is defined as the temperature at which 50 vol.% of α’-martensite is formed at a true tensile strain of 0.3 in metastable austenitic steels. It has been generally believed that the effect of carbon content on Md₃₀ was estimated to be identical to that of nitrogen as shown by Nohara’s equation. However, we found in this study that Md₃₀ in carbon-added steel is lower than that in nitrogen-added steel, which indicates that the effect of carbon content on the mechanical stability of austenite is more significant than that of nitrogen. In addition, the relationship between Md₃₀ and carbon and nitrogen content is not linear. The effect of carbon and nitrogen content on Md₃₀ is higher at lower carbon and nitrogen content region (<0.1%). As this effect was not considered in the previous study, the austenite-stabilizing effects of both the elements were underestimated. Therefore, in this study, new equations are proposed to accurately estimate Md₃₀ of a Fe-Cr-Ni alloy system. As a result, modified Md₃₀ equation is suggested as below:

Md₃₀(K) = 800 – 333 C eq – 10.3Si – 12.5Mn – 10.5Cr – 24.0Ni – 5.6Mo

Carbon equivalent, C_eq is a function of carbon and nitrogen concentrations and temperature.

C_eq = C + aN

a = 0.931 – 0.000281exp (0.0219T)

Above equations show that the difference in austenite-stabilizing effects of carbon and nitrogen increases with rising temperature, owing to the difference in stacking fault energy between carbon-added and nitrogen-added steels.