The kinetic competition between transport and oxidation of ferrous ions governs precipitation of corrosion products in carbonated concrete

Q2 Engineering
Matteo Stefanoni, Zhidong Zhang, U. Angst, B. Elsener
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引用次数: 30

Abstract

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.
铁离子的运移和氧化之间的动力学竞争决定了碳化混凝土中腐蚀产物的沉淀
腐蚀产物源于钢材的腐蚀并在混凝土孔隙系统中沉淀,可导致混凝土开裂和混凝土覆盖层剥落。相关过早的结构修复导致成本高。因此,需要可靠的定量模型,但目前还不存在。在这里,我们提出了一个新的概念模型来描述在腐蚀过程中在钢表面释放的铁离子的命运。我们的方法的关键新颖之处在于明确考虑了Fe2+在孔隙溶液中的氧化和运输动力学。这两个过程不断稀释Fe2+浓度,并与阳极铁溶解反应的Fe2+供应竞争。我们用一个数值模型来说明所描述的过程中哪一个是最快的。结果与实验数据吻合较好,表明在自然腐蚀条件下,Fe2+几乎达不到饱和水平,这使得腐蚀产物可以扩散到离钢毫米远的地方,而不必引起膨胀应力。然而,在加速腐蚀条件下,钢表面立即强制析出。这从根本上改变了开裂机制,并对此类试验和相关模型的相关性提出了质疑。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
RILEM Technical Letters
RILEM Technical Letters Materials Science-Materials Science (all)
CiteScore
5.00
自引率
0.00%
发文量
13
审稿时长
10 weeks
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