Review of interface tailoring techniques and applications to improve insulation performance

Interfaces between different materials, for instance, electrode-dielectrics and vacuum/air/SF6-insulators and oilpaper, are universal in high-voltage insulation systems. Targeted tailoring of the interfacial properties, e.g. chemical structures, micro-/nanoscale morphology, the charge injection barrier, trap states, and surface conductivity, is thought to be an effective approach to improve insulation properties such as breakdown and flashover strength, corona/tracking resistance, and wettability. In this article, the authors review recent progress in interface tailoring methods and their application to improve various insulation properties. The potential application scenarios of interface tailoring in different facilities are first summarised, and the desired insulation properties of various applications are highlighted. Interface tailoring methods are classified as physical/chemical surface modification and surface coating (inorganic, organic and composite), and the features of different techniques are described in detail. The structure-property relationships between interfacial states and various microscopic parameters such as charge injection barrier, trap distribution and surface conductivity are discussed together with the tailoring mechanisms for different insulation properties. Finally, the future development prospects of interface tailoring methods and their applications, e.g. multifunctional coating and stimuli-response smart coating, are presented.

Automated summary

Interfaces between different materials are essential in high-voltage insulation systems, and targeted tailoring of interfacial properties is considered an effective approach to enhance insulation properties. This article reviews recent progress in interface tailoring methods and their application to improve various insulation properties, discussing potential application scenarios and desired insulation properties. Classification of interface tailoring methods, including physical/chemical surface modification and surface coating, is provided, along with a discussion on structure-property relationships and future development prospects.