材料科学
异质结
铁电性
电容器
磁滞
聚合物
纳米复合材料
偶极子
光电子学
铁电聚合物
相(物质)
纳米技术
纳米尺度
纳米颗粒
储能
聚合物纳米复合材料
非易失性存储器
电子能带结构
宽禁带半导体
极地的
热传导
作者
Biyun Peng,Jian Wang,Weihao Dai,Yifei Zhang,Yingying Zheng,Yunchuan Xie,Sen Liang,Mingxu Xia
摘要
Ferroelectric polymers are constrained in high-power energy storage capacitors (ESCs) due to their hysteresis losses and low breakdown strength. We tackle this challenge via a dual-pronged strategy encompassing molecular-scale ferroelectric phase regulation and nanoscale heterojunction engineering. The incorporation of trifluoroethylene units into poly(vinylidene fluoride)-chlorotrifluoroethylene disrupts the ferroelectric long-range order, inducing a relaxor state with dynamic polar nanoregions (PNRs) to minimize hysteresis. Simultaneously, ZnO@ZnS nanoparticles refine PNRs and introduce deep charge traps via interfacial band engineering, thereby drastically suppressing electrical conduction. This synergistic strategy employs phase regulation to reduce dipolar loss and heterojunction engineering to curb conduction loss, leading to a greatly increased breakdown strength and reduced dissipation. The resulting nanocomposite achieves a high discharged energy density of 23.8 J cm−3 at 550 MV m−1 with 80% efficiency and robust cycling stability (>5000 cycles) and establishes a transformative pathway for ultrahigh-performance ESCs.
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