材料科学
电介质
铁电性
电容器
纳米复合材料
极化(电化学)
介电损耗
铁电聚合物
光电子学
储能
复合材料
聚酰亚胺
电场位移场
聚合物
聚合物纳米复合材料
陶瓷
铁电陶瓷
聚合物电容器
高-κ电介质
纳米技术
纳米颗粒
极化密度
功率密度
电场
作者
Yao Su,Yuxin Jia,Xin Yang,Shuwen Zhu,Yongbo Fan,Weijia Wang,Huiqing Fan
出处
期刊:Small methods
[Wiley]
日期:2025-11-17
卷期号:9 (12): e01632-e01632
标识
DOI:10.1002/smtd.202501632
摘要
Abstract Polymer dielectrics exhibit remarkable advantages, including high power density, elevated operating voltage, and excellent processability. In dielectric films, the ferroelectric domain architecture and its flipping dynamics are pivotal for energy storage, as they govern electric displacement and charge–discharge efficiency. A widely adopted strategy to enhance polarization involves incorporating ferroelectric ceramics into the polymer matrix. However, this approach inevitably induces higher dielectric loss and compromises charge–discharge efficiency. Here a ferroelectric‐paraelectric KNbO 3 ‐SrTiO 3 nanofillers is introduced that effectively suppress ferroelectric domain volume, mitigate hysteresis, and reduces remnant polarization. Phase‐field simulations corroborate that domain polarization undergoes more facile reversal, substantially minimizing dielectric loss while preserving high polarization. To further enhance the breakdown strength ( E b ), the KNbO 3 ‐SrTiO 3 filler is encapsulated with an Al 2 O 3 coating. Consequently, the KNbO 3 ‐0.2 SrTiO 3 @Al 2 O 3 /FPI nanocomposite film achieves outstanding dielectric capacitor performance, featuring an impressive energy storage density of 6.09 J cm −3 , a higher displacement difference ( D max ‐ D r ) of 2.08 µC cm −3 , and an E b of 611 MV m −1 at 150 °C under 100 Hz. This work presents a forward‐thinking strategy for the scalable industrial production and deployment of high‐performance dielectric capacitors.
科研通智能强力驱动
Strongly Powered by AbleSci AI