Inhibition of Defect-Induced Ice Nucleation, Propagation, and Adhesion by Bioinspired Self-Healing Anti-Icing Coatings

Anti-icing coatings on outdoor infrastructures inevitably suffer from mechanical injuries in numerous icing scenarios such as hailstorms, sandstorms, impacts of foreign objects, and icing–deicing cycles. Herein, the mechanisms of surface-defect-induced icing are clarified. At the defects, water mole...

Descripción completa

Detalles Bibliográficos
Autores principales: Tian, Shu, Li, Ruiqi, Liu, Xinmeng, Wang, Jiancheng, Yu, Junyu, Xu, Sijia, Tian, Yunqing, Yang, Jing, Zhang, Lei
Formato: Online Artículo Texto
Lenguaje:English
Publicado: AAAS 2023
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10194051/
https://www.ncbi.nlm.nih.gov/pubmed/37214197
http://dx.doi.org/10.34133/research.0140
_version_ 1785043939044098048
author Tian, Shu
Li, Ruiqi
Liu, Xinmeng
Wang, Jiancheng
Yu, Junyu
Xu, Sijia
Tian, Yunqing
Yang, Jing
Zhang, Lei
author_facet Tian, Shu
Li, Ruiqi
Liu, Xinmeng
Wang, Jiancheng
Yu, Junyu
Xu, Sijia
Tian, Yunqing
Yang, Jing
Zhang, Lei
author_sort Tian, Shu
collection PubMed
description Anti-icing coatings on outdoor infrastructures inevitably suffer from mechanical injuries in numerous icing scenarios such as hailstorms, sandstorms, impacts of foreign objects, and icing–deicing cycles. Herein, the mechanisms of surface-defect-induced icing are clarified. At the defects, water molecules exhibit stronger adsorption and the heat transfer rate increases, accelerating the condensation of water vapor as well as ice nucleation and propagation. Moreover, the ice–defect interlocking structure increases the ice adhesion strength. Thus, a self-healing (at −20 °C) antifreeze-protein (AFP)-inspired anti-icing coating is developed. The coating is based on a design that mimics the ice-binding and non-ice-binding sites in AFPs. It enables the coating to markedly inhibit ice nucleation (nucleation temperature < −29.4 °C), prevent ice propagation (propagation rate < 0.00048 cm(2)/s), and reduce ice adhesion on the surface (adhesion strength < 38.9 kPa). More importantly, the coating can also autonomously self-heal at −20 °C, as a result of multiple dynamic bonds in its structure, to inhibit defect-induced icing processes. The healed coating sustains high anti-icing and deicing performance even under various extreme conditions. This work reveals the in-depth mechanism of defect-induced ice formation as well as adhesion, and proposes a self-healing anti-icing coating for outdoor infrastructures.
format Online
Article
Text
id pubmed-10194051
institution National Center for Biotechnology Information
language English
publishDate 2023
publisher AAAS
record_format MEDLINE/PubMed
spelling pubmed-101940512023-05-19 Inhibition of Defect-Induced Ice Nucleation, Propagation, and Adhesion by Bioinspired Self-Healing Anti-Icing Coatings Tian, Shu Li, Ruiqi Liu, Xinmeng Wang, Jiancheng Yu, Junyu Xu, Sijia Tian, Yunqing Yang, Jing Zhang, Lei Research (Wash D C) Research Article Anti-icing coatings on outdoor infrastructures inevitably suffer from mechanical injuries in numerous icing scenarios such as hailstorms, sandstorms, impacts of foreign objects, and icing–deicing cycles. Herein, the mechanisms of surface-defect-induced icing are clarified. At the defects, water molecules exhibit stronger adsorption and the heat transfer rate increases, accelerating the condensation of water vapor as well as ice nucleation and propagation. Moreover, the ice–defect interlocking structure increases the ice adhesion strength. Thus, a self-healing (at −20 °C) antifreeze-protein (AFP)-inspired anti-icing coating is developed. The coating is based on a design that mimics the ice-binding and non-ice-binding sites in AFPs. It enables the coating to markedly inhibit ice nucleation (nucleation temperature < −29.4 °C), prevent ice propagation (propagation rate < 0.00048 cm(2)/s), and reduce ice adhesion on the surface (adhesion strength < 38.9 kPa). More importantly, the coating can also autonomously self-heal at −20 °C, as a result of multiple dynamic bonds in its structure, to inhibit defect-induced icing processes. The healed coating sustains high anti-icing and deicing performance even under various extreme conditions. This work reveals the in-depth mechanism of defect-induced ice formation as well as adhesion, and proposes a self-healing anti-icing coating for outdoor infrastructures. AAAS 2023-05-18 /pmc/articles/PMC10194051/ /pubmed/37214197 http://dx.doi.org/10.34133/research.0140 Text en Copyright © 2023 Shu Tian et al. https://creativecommons.org/licenses/by/4.0/Exclusive licensee Science and Technology Review Publishing House. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution License (CC BY 4.0) (https://creativecommons.org/licenses/by/4.0/) .
spellingShingle Research Article
Tian, Shu
Li, Ruiqi
Liu, Xinmeng
Wang, Jiancheng
Yu, Junyu
Xu, Sijia
Tian, Yunqing
Yang, Jing
Zhang, Lei
Inhibition of Defect-Induced Ice Nucleation, Propagation, and Adhesion by Bioinspired Self-Healing Anti-Icing Coatings
title Inhibition of Defect-Induced Ice Nucleation, Propagation, and Adhesion by Bioinspired Self-Healing Anti-Icing Coatings
title_full Inhibition of Defect-Induced Ice Nucleation, Propagation, and Adhesion by Bioinspired Self-Healing Anti-Icing Coatings
title_fullStr Inhibition of Defect-Induced Ice Nucleation, Propagation, and Adhesion by Bioinspired Self-Healing Anti-Icing Coatings
title_full_unstemmed Inhibition of Defect-Induced Ice Nucleation, Propagation, and Adhesion by Bioinspired Self-Healing Anti-Icing Coatings
title_short Inhibition of Defect-Induced Ice Nucleation, Propagation, and Adhesion by Bioinspired Self-Healing Anti-Icing Coatings
title_sort inhibition of defect-induced ice nucleation, propagation, and adhesion by bioinspired self-healing anti-icing coatings
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10194051/
https://www.ncbi.nlm.nih.gov/pubmed/37214197
http://dx.doi.org/10.34133/research.0140
work_keys_str_mv AT tianshu inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings
AT liruiqi inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings
AT liuxinmeng inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings
AT wangjiancheng inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings
AT yujunyu inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings
AT xusijia inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings
AT tianyunqing inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings
AT yangjing inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings
AT zhanglei inhibitionofdefectinducedicenucleationpropagationandadhesionbybioinspiredselfhealingantiicingcoatings

Ejemplares similares