Falzone, G.
, Balonis, M.
, Bentz, D.
, Jones, S.
and Sant, G.
(2017),
Anion Capture and Exchange by Functional Coatings: New Routes to Mitigate Steel Corrosion in Concrete Infrastructure, Cement and Concrete Research, [online], https://doi.org/10.1016/j.cemconres.2017.08.021, https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=921604
(Accessed April 23, 2024)
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Anion Capture and Exchange by Functional Coatings: New Routes to Mitigate Steel Corrosion in Concrete Infrastructure
Published
Author(s)
Gabriel Falzone, Magdalena Balonis, , , Gaurav Sant
Abstract
Chloride induced corrosion is a major cause of degradation of reinforced concrete infrastructure. While the binding of chloride ions (Cl-) by cementitious phases is known to delay corrosion, this approach has not been systematically exploited as a mechanism to increase structural service-life. Recently, Falzone et al. [Cement and Concrete Research 72, 54-68 (2015)] proposed calcium aluminate cement (CAC) formulations containing NO3-AFm as anion-exchange coatings capable of binding large quantities of Cl-, while simultaneously releasing corrosion-inhibiting NO3- species. To examine the viability of this concept, Cl- binding isotherms and ion-diffusion coefficients of a series of hydrated CAC formulations containing admixed Ca(NO3)2 (CN) were quantified. This data was input into a multi-species Nernst-Planck (NP) formulation and solved for a typical bridge-deck geometry using the finite element method (FEM). For exposure conditions corresponding to seawater, the results indicate that Cl- scavenging CAC coatings (i.e., top-layers) can significantly delay the time to corrosion (e.g., 5 ≤ df ≤ 10, where df is the steel corrosion initiation delay factor [unitless]) as compared to traditional OPC-based systems for a fixed cover depth; as identified by thresholds of Cl-/OH- or Cl-/NO3- (molar) ratios in solution. The roles of hindered ionic diffusion, and the passivation of the reinforcing steel rendered by NO3- are also discussed.Citation
Cement and Concrete Research
Volume
101
Pub Type
Journals
Download Paper
Keywords
Corrosion, finite element analysis, calcium aluminate cement, chloride, calcium nitrate
Citation
Created September 3, 2017, Updated October 12, 2021