Dynamic study on the anodic dissolution of 304 stainless steel with elastic stress in sodium chloride solution

[Display omitted] •Tensile stress and large compressive stress promote the anodic dissolution of 304 SS.•Small compressive stress makes the passive film more compact and dense.•Digital holography is a promising technology for the study of metal mechanochemistry. Effects of elastic stresses on the an...

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Bibliographic Details
Published in:Electrochemistry communications 2025-01, Vol.170, p.107847, Article 107847
Main Authors: Zhou, Jiayue, Ding, Guangming, Li, Qincheng, Yang, Pengyu, Zhu, Yongyan
Format: Article
Language:English
Subjects:
304 stainless steel
Anodic dissolution
Compressive stress
Digital holography
Tensile stress
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Summary:[Display omitted] •Tensile stress and large compressive stress promote the anodic dissolution of 304 SS.•Small compressive stress makes the passive film more compact and dense.•Digital holography is a promising technology for the study of metal mechanochemistry. Effects of elastic stresses on the anodic dissolution of 304 stainless steel (SS) in 0.5 mol·dm−3 NaCl solution have been investigated by potentiodynamic polarization technique, scanning electron microscopy (SEM) and digital holography (DH). From the polarization curves, the SEM morphologies and the phase reconstruction maps, the effects of tensile and compressive stresses on the anodic dissolution of 304 SS have been analyzed. The tensile stresses and the large compressive stresses promote the anodic dissolution and increase the pitting susceptibility of 304 SS. However, the small compressive stress inhibits the anodic dissolution and decreases the pitting susceptibility of 304 SS. In this study, DH was used to observe the surface reactivity distribution of both the tensile and compressive stressed regions of the same sample. The conclusions obtained from the in-situ observations with DH are consistent with those drawn from the electrochemical measurements and the surface morphologies.
ISSN:1388-2481
DOI:10.1016/j.elecom.2024.107847