Ultrahigh Energy Density of Antiferroelectric PbZrO<sub>3</sub>‐Based Films at Low Electric Field
Dongxu Li, Xiangyu Meng, E Zhou, Xiaoxiao Chen, Zhonghui Shen, Qinghu Guo, Zhonghua Yao, Minghe Cao, Jinsong Wu, Shujun Zhang, Hanxing Liu, Hua Hao
Abstract
Abstract Dielectric capacitors play a vital role in advanced electronics and power systems as a medium of energy storage and conversion. Achieving ultrahigh energy density at low electric field/voltage, however, remains a challenge for insulating dielectric materials. Taking advantage of the phase transition in antiferroelectric (AFE) film PbZrO 3 (PZO), a small amount of isovalent (Sr 2+ ) / aliovalent (La 3+ ) dopants are introduced to form a hierarchical domain structure to increase the polarization and enhance the backward switching field E A simultaneously, while maintaining a stable forward switching field E F . An ultrahigh energy density of 50 J cm −3 is achieved for the nominal Pb 0.925 La 0.05 ZrO 3 (PLZ5) films at low electric fields of 1 MV cm −1 , exceeding the current dielectric energy storage films at similar electric field. This study opens a new avenue to enhance energy density of AFE materials at low field/voltage based on a gradient‐relaxor AFE strategy, which has significant implications for the development of new dielectric materials that can operate at low field/voltage while still delivering high energy density.