Mimosa inspired intelligent anti-corrosive composite coating by incorporating lignin and pyridine derivatives grafted graphene oxide

•Oxidized graphene was modified by lignin and pyridine derivatives.•Inspired by mimosa, a long-term anti-corrosion composite coating was prepared.•Pyridine group and Fe2+ had a strong binding energy (-369.99 kcal/mol). Although the coating can effectively prevent metal corrosion, it is easy to form...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2024-03, Vol.483, p.149316, Article 149316
Main Authors: Xu, Chang-An, Li, Xingchi, Tong, Zhengbang, Chu, Zhuangzhuang, Fang, Heng, Hu, Yang, Chen, Xudong, Yang, Zhuohong
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Language:English
Subjects:
Anti-corrosion
Coating
Graphene oxide
Lignin
Pyridine derivative
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cited_by cdi_FETCH-LOGICAL-c297t-7fcef4986d30a1497979bc326467065ac0de66c5997e1677c5939a00547d6f873
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container_title Chemical engineering journal (Lausanne, Switzerland : 1996)
container_volume 483
creator Xu, Chang-An
Li, Xingchi
Tong, Zhengbang
Chu, Zhuangzhuang
Fang, Heng
Hu, Yang
Chen, Xudong
Yang, Zhuohong
description •Oxidized graphene was modified by lignin and pyridine derivatives.•Inspired by mimosa, a long-term anti-corrosion composite coating was prepared.•Pyridine group and Fe2+ had a strong binding energy (-369.99 kcal/mol). Although the coating can effectively prevent metal corrosion, it is easy to form micro-pores and micro-cracks during the curing process, and the coating is inevitably damaged by the external environment during use, resulting in a reduction in its protective ability, thereby shortening the service life of the substrate. Inspired by the stress closure function of mimosa, an intelligent anti-corrosion coating with stress closure function against corrosion products (Fe2+) was prepared by using pyridine derivatives and lignin grafted graphene oxide (ATGO). By density functional theory calculation, the binding energy of pyridine group and Fe2+ was −369.99 kcal/mol, and their strong complexation would facilitate the formation of a dense protective layer at the metal corrosion interface. The test results showed that ATGO-CM coating had high fracture strength (86.9 MPa) and adhesion strength (2.03 MPa), as well as low water vapor permeability (1.3 × 10-6 g m−1 day−1 Pa−1). Electrochemical testing denoted that after soaking in 3.5 wt% saline solution for 100 days, the impedance modulus of the ATGO-CM coating remained at 5.36 × 109 Ω·cm2 at low frequencies (f = 0.01 Hz), which was two orders of magnitude higher than the blank group. Through scratch experiments showed that the complexation effect of pyridine groups and corrosive products could significantly improve the corrosion resistance of the coating, with Rct value of 1.8 × 104 Ω cm2 for the damaged coating, one order of magnitude higher than the blank group. This work not only provided a reference for the preparation of intelligent anti-corrosion coatings with bionic functions, but also increased the added value of biomass materials.
doi_str_mv 10.1016/j.cej.2024.149316
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Although the coating can effectively prevent metal corrosion, it is easy to form micro-pores and micro-cracks during the curing process, and the coating is inevitably damaged by the external environment during use, resulting in a reduction in its protective ability, thereby shortening the service life of the substrate. Inspired by the stress closure function of mimosa, an intelligent anti-corrosion coating with stress closure function against corrosion products (Fe2+) was prepared by using pyridine derivatives and lignin grafted graphene oxide (ATGO). By density functional theory calculation, the binding energy of pyridine group and Fe2+ was −369.99 kcal/mol, and their strong complexation would facilitate the formation of a dense protective layer at the metal corrosion interface. The test results showed that ATGO-CM coating had high fracture strength (86.9 MPa) and adhesion strength (2.03 MPa), as well as low water vapor permeability (1.3 × 10-6 g m−1 day−1 Pa−1). Electrochemical testing denoted that after soaking in 3.5 wt% saline solution for 100 days, the impedance modulus of the ATGO-CM coating remained at 5.36 × 109 Ω·cm2 at low frequencies (f = 0.01 Hz), which was two orders of magnitude higher than the blank group. Through scratch experiments showed that the complexation effect of pyridine groups and corrosive products could significantly improve the corrosion resistance of the coating, with Rct value of 1.8 × 104 Ω cm2 for the damaged coating, one order of magnitude higher than the blank group. 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Electrochemical testing denoted that after soaking in 3.5 wt% saline solution for 100 days, the impedance modulus of the ATGO-CM coating remained at 5.36 × 109 Ω·cm2 at low frequencies (f = 0.01 Hz), which was two orders of magnitude higher than the blank group. Through scratch experiments showed that the complexation effect of pyridine groups and corrosive products could significantly improve the corrosion resistance of the coating, with Rct value of 1.8 × 104 Ω cm2 for the damaged coating, one order of magnitude higher than the blank group. 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subjects Anti-corrosion
Coating
Graphene oxide
Lignin
Pyridine derivative
title Mimosa inspired intelligent anti-corrosive composite coating by incorporating lignin and pyridine derivatives grafted graphene oxide
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