One-Dimensional Pit Experiments and Modeling to Determine Critical Factors for Pit Stability and Repassivation

Abstract: Experiments on stainless steel artificial pit electrodes in sodium chloride were used to inform a diffusion model developed based on the mass transport behavior within a one-dimensional corroding pit. Measurable estimates of the dissolution flux as well as the potential describing the conditions of interest were obtained from experiment as the one-dimensional pit stability product under a salt film (i · x) saltfilm and the repassivation potential E rp , respectively. These parameter estimates were acquired as … Show more

“…1,4,5 In the past several decades, the critical pit stability product and critical solution chemistry during stable pit propagation under a salt film have been the focus of many researchers. [7][8][9][10][11][12][13][14][15] In this regard, numerous experimental and mass transport modeling works focused on one-dimensional (1D) pit propagation to estimate the pit stability product. 8,9,[16][17][18][19][20][21] The most common mass transport method is based on 1D Fick's law of diffusion.…”

“…[7][8][9][10][11][12][13][14][15] In this regard, numerous experimental and mass transport modeling works focused on one-dimensional (1D) pit propagation to estimate the pit stability product. 8,9,[16][17][18][19][20][21] The most common mass transport method is based on 1D Fick's law of diffusion. For example, Tester et al used 1D Fick's law of diffusion to calculate the time evolution of the dissolution current density during potentiostatic polarization using a 1D pit setup.…”

“…Jun et al, and Srinivasan et al have demonstrated the importance of solution viscosity on diffusivity, indicating that the diffusion coefficient would decrease with an increase in pit depth 8,19,31. Thus, it was necessary to consider a variable diffusion coefficient due to the concentration gradient inside the pit.…”

On the Critical Factors for Estimating the Pit Stability Product under a Salt Film

“…1,4,5 In the past several decades, the critical pit stability product and critical solution chemistry during stable pit propagation under a salt film have been the focus of many researchers. [7][8][9][10][11][12][13][14][15] In this regard, numerous experimental and mass transport modeling works focused on one-dimensional (1D) pit propagation to estimate the pit stability product. 8,9,[16][17][18][19][20][21] The most common mass transport method is based on 1D Fick's law of diffusion.…”

“…[7][8][9][10][11][12][13][14][15] In this regard, numerous experimental and mass transport modeling works focused on one-dimensional (1D) pit propagation to estimate the pit stability product. 8,9,[16][17][18][19][20][21] The most common mass transport method is based on 1D Fick's law of diffusion. For example, Tester et al used 1D Fick's law of diffusion to calculate the time evolution of the dissolution current density during potentiostatic polarization using a 1D pit setup.…”

“…Jun et al, and Srinivasan et al have demonstrated the importance of solution viscosity on diffusivity, indicating that the diffusion coefficient would decrease with an increase in pit depth 8,19,31. Thus, it was necessary to consider a variable diffusion coefficient due to the concentration gradient inside the pit.…”

On the Critical Factors for Estimating the Pit Stability Product under a Salt Film

“…The simplest of mechanistic models consider mass transport of solute species (e.g., metal or hydrogen ions) in the solution environment based on the Fick's law of diffusion [36]. Therefore, the 1-D Fickian diffusion model has been widely used to simulate the evolution of the chemistry inside the 1-D pit [37][38][39][40][41][42]. Srinivasan et al used this model to evaluate the effect of the external hemispherical boundary layer on the cation flux inside the pit [40] and to demonstrate the dilution of cations near the corroding surface when repassivation happens [41,42].…”

“…Therefore, the 1-D Fickian diffusion model has been widely used to simulate the evolution of the chemistry inside the 1-D pit [37][38][39][40][41][42]. Srinivasan et al used this model to evaluate the effect of the external hemispherical boundary layer on the cation flux inside the pit [40] and to demonstrate the dilution of cations near the corroding surface when repassivation happens [41,42]. Jun et al applied the similar model to analyze the effects of chloride concentration and temperature on 1-D pit growth [39].…”

Numerical Investigation of Critical Electrochemical Factors for Localized Corrosion using a Multi-species Reactive Transport Model

Crystallographic texture can be rapidly determined by electrochemical surface analytics