CaAl–NO2 LDH hybrid self-healing microcapsules with chloride triggering: Towards synergistic corrosion resistance

The synergistic corrosion resistance microcapsules (SCRMs) were synthesized by utilizing CaAl–NO2 LDH (NO2-LDH) as chloride trigger and high-performance corrosion inhibitor to hybridize self-healing microcapsules. The morphology, chemical structure and self-healing performance of the microcapsules w...

Full description

Saved in:
Bibliographic Details
Published in:Composites. Part B, Engineering Engineering, 2023-09, Vol.264, p.110902, Article 110902
Main Authors: Wang, Xingang, Zhu, Jielu, Zou, Fubing, Zhou, Naigen, Zhong, Yiwei
Format: Article
Language:English
Subjects:
Chloride triggering
Corrosion resistance
First-principles
Microcapsules
NO2-LDH
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The synergistic corrosion resistance microcapsules (SCRMs) were synthesized by utilizing CaAl–NO2 LDH (NO2-LDH) as chloride trigger and high-performance corrosion inhibitor to hybridize self-healing microcapsules. The morphology, chemical structure and self-healing performance of the microcapsules were characterized. The chloride triggering and corrosion resistance property of the SCRMs were evaluated. The interaction of hybrid wall, NO2-LDH and chloride ion was calculated by first-principles. The findings revealed that the microcapsules show regular spherical with obvious core-wall structure. EDS and chemical structure measurements confirmed that NO2-LDH was successfully embedded within the microcapsule wall. The SCRMs showed excellent corrosion resistance property in simulated chloride-contaminated concrete pore solution (SCPS), and the highest inhibition efficiency was 97.85%. The microcapsule wall was hybridized by NO2-LDH species through chemical pathways. The first-principles calculation results confirmed that Ca and Al species are the main factors for chloride ion immobilization of hybrid wall. The ion exchange process of microcapsules destroys the molecular force of NO2-LDH@ethyl cellulose hybrid wall and improves the mechanical triggering efficiency of microcapsules in cement-based composites. [Display omitted] •CaAl–NO2 LDH was employed as the chloride trigger and corrosion inhibitor to prepare synergistic corrosion resistance microcapsules.•The mechanism of hybridization and corrosion resistance was discussed through experimental characterization and first-principles calculation.•The mechanical triggering efficiency of microcapsules in cement-based composites is improved by ion exchange.•The corrosion resistance property of rebar in cement-based composites is enhanced by synergistic corrosion resistance microcapsules through the triple effect.
ISSN:1359-8368
1879-1069
DOI:10.1016/j.compositesb.2023.110902