Improved Insulating Properties of Polymer Dielectric by Constructing Interfacial Composite Coatings

Overview

Journal Materials (Basel)

Publisher MDPI

Date 2024 Jan 11

PMID 38203912

Authors

Jia-Xuan Wang

Yong-Gang Chen

Ji-Ming Chen

Zhi-Hui Yin

Chun-Song Chen

Yi-Fei Li

Ting Deng

Xiao-Bo Guo

Ming-Xiao Zhu

Affiliations

Soon will be listed here.

Abstract

Polymeric dielectrics exhibit remarkable dielectric characteristics and wide applicability, rendering them extensively employed within the domain of electrical insulation. Nevertheless, the electrical strength has always been a bottleneck, preventing its further utilization. Nanocomposite materials can effectively improve insulation strength, but uniform doping of nanofillers in engineering applications is a challenge. Consequently, a nanocomposite interfacial coating was meticulously designed to interpose between the electrode and the polymer, which can significantly improve DC breakdown performance. Subsequently, the effects of filler concentration and coating duration on DC breakdown performance, high field conductivity, and trap distribution characteristics were analyzed. The results indicate that the composite coating introduces deep traps between the electrode-polymer interface, which enhances the carrier confinement, resulting in reduced conductivity and enhanced DC breakdown strength. The incorporation of a composite coating at the interface between the electrode and polymer presents novel avenues for enhancing the dielectric insulation of polymers.

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