6533b861fe1ef96bd12c4a43

RESEARCH PRODUCT

Modeling and numerical simulation of the propagation of pitting corrosion of iron in chlorinated medium : contribution to the evaluation of the durability of carbon steels in geological storage conditions

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This study deals with the understanding of the mechanisms of pitting corrosion susceptible to occur on carbon steel selected for high level nuclear waste containers. Transport/reaction models have been developed in order to simulate, by finite element method, the propagation of a pit on iron in chlorinated medium. For conservative models, pit is activated by imposing a potential on metal. Thanks to different parametric studies (geometry, environment…) simulations have permitted to classify, by severity order, the factors responsible of the increase or the inhibition of the localized corrosion rate. Otherwise, experiments on occluded (called « lead-in-pencil ») electrodes confirm that confinement favors the formation of a salt film at the bottom of the pit. Finally, the simulation of galvanic coupling between the pit and the surrounding cathodic surface has permitted to describe the realistic evolution of the localized corrosion rate in aerated medium and for free corroding conditions. The analysis of the results from these three ways of investigation has demonstrated that the ohmic drop inside the pit is the most important factor controlling his growing. In most study cases, any increase of this ohmic drop (due to precipitation, confinement or augmentation of the cathodic /anodic surfaces ratio), leads to a faster corrosion rate of the surrounding surface. This phenomenon is called “opening” of the pit. The progression at the pit bottom for a pH-dependant oxidation rate is still to confirm. In order to simulate the long term behavior of iron during pitting, in storage application, new models require a more accurate determination of the environment conditions, dissolution and precipitation laws