The kinetic competition between transport and oxidation of ferrous ions governs precipitation of corrosion products in carbonated concrete
Auteur(s): |
Matteo Stefanoni
Zhidong Zhang Ueli Angst Bernhard Elsener |
---|---|
Médium: | article de revue |
Langue(s): | anglais |
Publié dans: | RILEM Technical Letters, avril 2019, v. 3 |
Page(s): | 8-16 |
DOI: | 10.21809/rilemtechlett.2018.57 |
Abstrait: |
Corrosion products, originating from steel corrosion and precipitating in the concrete pore system, can lead to concrete cracking and to spalling of the concrete cover. Related premature structural repair causes high costs. Thus, reliable quantitative models are needed, which currently do not exist. Here, we present a new conceptual model to describe the fate of ferrous ions that are released at the steel surface during the corrosion process. The key novelty of our approach can be found in explicitly considering the kinetics of oxidation and transport of Fe2+ in the pore solution. These two processes constantly dilute the Fe2+ concentration and are in competition with the supply of Fe2+ from the anodic iron dissolution reaction. We use a numerical model to elucidate which of the described processes is the fastest. The results find good agreement with experimental data and reveal that under natural corrosion conditions, Fe2+ hardly reach the saturation level, which permits the diffusion of corrosion products up to millimeters away from the steel without necessarily leading to expansive stresses. Under accelerated corrosion conditions, however, precipitation is forced immediately at the steel surface. This fundamentally changes the cracking mechanism and questions the relevance of such tests and related models. |
License: | Cette oeuvre a été publiée sous la license Creative Commons Attribution 4.0 (CC-BY 4.0). Il est autorisé de partager et adapter l'oeuvre tant que l'auteur est crédité et la license est indiquée (avec le lien ci-dessus). Vous devez aussi indiquer si des changements on été fait vis-à-vis de l'original. |
1.76 MB
- Informations
sur cette fiche - Reference-ID
10412182 - Publié(e) le:
08.02.2020 - Modifié(e) le:
02.06.2021