材料科学
聚丙烯
复合材料
弹性体
增容
空间电荷
热稳定性
复合数
热的
相容性(地球化学)
相(物质)
共价键
散热膏
电场
胶粘剂
马来酸酐
载流子
动态力学分析
热变形温度
机械负荷
甲基丙烯酸酯
作者
Hongzhe Zhang,Wenye Zhang,Wenjie Huang,Yun Zhao
出处
期刊:Energy & environmental materials
[Wiley]
日期:2026-01-25
被引量:1
摘要
Polypropylene is a promising eco‐friendly cable insulation material owing to its impressive electrical properties, yet its inherently inferior mechanical performance limits direct application. Blending with elastomers is commonly employed to address mechanical deficiencies in polypropylene, but it induces phase incompatibility and space charge accumulation, compromising insulation performance. Moreover, the interfaces are prone to damage under high mechanical or electrical stress, and such damage is often irreversible, hindering the long‐term stability of the composites. Herein, a nitrogen‐boron crosslinked polypropylene/polyolefin elastomer (NBPP) composite is developed through post‐modification and dynamic covalent chemistry. The dynamic bonds at the interface link immiscible phases and localized charge migration, while trap‐rich regions in the bulk phase suppress carrier mobility. This interface‐guided, bulk‐trapped structure effectively enhances phase compatibility and reduces space charge accumulation. The optimized sample achieves a breakdown strength of 572 kV mm −1 and minimal electric field distortion (~8.6% at 70 °C under 50 kV mm −1 ). The reversible nature of the borate ester bonds enables self‐healing under thermal activation, allowing recovery from multiple types of damage and repeated thermal reprocessing. This approach provides an innovative strategy for high‐performance, sustainable, and self‐healing polymeric insulation materials for next‐generation high‐voltage direct current transmission systems.
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