First-principles modeling of passivation behaviors of stainless steels in corrosive environments

doi:10.1016/j.jmst.2024.11.082

Abstract

Abstract: Accurately determining the Flade potential (EFlade) is of signiﬁcant importance in the design of novel corrosion-resisting alloys. However, due to the complex nature of the EFlade influenced by several factors including compositions of the alloys and corrosive solutions, there is currently a lack of truly predictive ab initio model. Here, we established the critical potential condition required for passivation in acidic solutions containing chloride ions (Cl-) by developing an ab initio model that incorporates the potential drop from the metal electrode to the solution, considering tunneling of electrons at metal/ﬁlm interface, breakdown of the ﬁlm, and electrochemical adsorption reactions at ﬁlm/solution interface. These param-eters were derived from the work function of the alloy substrate and passivation ﬁlm, the band gap of the passivation ﬁlm, and the Gibbs free energy of adsorption on the passivation ﬁlm, all of which can be obtainable from ﬁrst-principles calculations. This theoretical model has been successfully validated for alloyed stainless steel, exhibiting a remarkable agreement with experimental results. Importantly, en-abled by the model, we have identiﬁed several alloying elements (i.e., Ta, W, Os, and Ir) that can effec-tively lower the EFlade of the stainless steel. This work constitutes an important step forward in modeling complex passivation behaviors from ﬁrst-principles, providing a useful tool for the design of corrosion-resisting alloys.

Key words: Passivation, Modeling, First-principles calculation, Stainless steel

Wenjing Xu, Ergen Bao, Yueqi Si, Hui Ma, Peitao Liu, Yan Sun, Yongpeng Shi, Xing-Qiu Chen. First-principles modeling of passivation behaviors of stainless steels in corrosive environments[J]. J. Mater. Sci. Technol., 2025, 229: 58-66.

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