Abstract
New perspectives arise from the application of the finite difference method (FDM), which incorporates the dynamic change in sub-surface hydrogen concentration (C
S
) on the steel surface, for analyzing hydrogen permeation behaviors under the combined action of sour corrosion and tensile loading. With this modified-FDM modeling and quantified C
S
values, it can be mechanistically understood that the loaded steel undergoes a cycle consisting of a higher hydrogen evolution rate on the surface, weakening the stability of the corrosion scale (FeSX) with more defects, and increased electrical conductivity. This leads to maintaining higher C
S
level, based on a higher cathodic reduction reaction.
Funder
National Research Foundation of Korea
Publisher
The Electrochemical Society