A novel UV, moisture and magnetic field triple-response smart insulating material achieving highly targeted self-healing based on nano-functionalized microcapsules

材料科学 自愈 紫外线 复合材料 智能材料 紫外线 环氧树脂 固化(化学) 水分 复合数 纳米技术 光电子学 医学 病理 替代医学
作者
Potao Sun,Fengqi Liu,Wenxia Sima,Tao Yuan,Ming Yang,Liang Chen,Mingke Zhao,Ze Yin
出处
期刊:Nanoscale [Royal Society of Chemistry]
卷期号:14 (6): 2199-2209 被引量:14
标识
DOI:10.1039/d1nr04600d
摘要

During the long-term operation of solid insulation materials, strong electric fields and mechanical stress cause electrical trees and cracks that are undetectable and irreversible, leading to the failure of electronic and electrical devices. A promising means of protecting against these problems is to endow the insulating materials with some self-healing capability alongside their excellent intrinsic properties. However, this has proved extremely challenging. In this paper, we describe an ultraviolet light, moisture, and magnetic field triple-response microcapsule that enables epoxy resin materials to heal themselves against various forms of damage without affecting the intrinsic performance of the matrix. In particular, microcapsules wrapped inside functional shells containing Fe3O4 nanoparticles are precisely controlled by a targeted magnetic field and distributed in the vulnerable area of the insulation materials, resulting in a high healing rate at low doping concentrations. Using the in situ ultraviolet light emitted by the electrical trees, artificial ultraviolet light, and moisture in the operating environment, it is possible to induce active or passive curing of the healing agent, thus realizing the intelligent, non-contact, and targeted self-healing of mechanical cracks and electrical tree damage. This method opens an avenue toward the development of self-healing insulation materials for electrical and electronic applications.

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