Galvanic corrosion is an electrochemical phenomenon that arises due to the coupling of two different metals in an electrolytic environment, resulting in the deterioration of the less noble metal at an accelerated rate. This phenomenon poses a significant challenge in the economy of mixed-metal assemblies in many industrial applications due to the high maintenance and replacement expenditures that such systems incur. In this study, a stainless steel tube was galvanically coupled with a carbon steel fitting, and both were immersed in a chloride solution to study the galvanic interactions. The electrochemical processes associated with galvanic corrosion were simulated using a finite element multiphysics modeling approach (COMSOL Multiphysics). The simulations reproduced the metal–electrolyte interface potential and current density as well as the preferential anodic dissolution of carbon steel over stainless steel, which was observed during the coupled polarization. The numerical results matched the results predicted using assumptions for the steels’ electrochemical behavior. The results of the study confirmed that finite element simulation is an effective means of modeling galvanic corrosion and optimizing the design and life of metal component assemblies that are subjected to highly aggressive environments such as high-chloride environments. The numerical results matched the trends observed from experimentation and those previously reported in the literature and serve to provide qualitative and semi-quantitative insight regarding galvanic corrosion mechanisms instead of complete corrosion predictions regarding long-term corrosion behavior.
Elidrissi et al. (Tue,) studied this question.