极化(电化学)
材料科学
电介质
偶极子
涡流
极地的
电容器
凝聚态物理
拓扑(电路)
储能
电容感应
电压
光电子学
工作(物理)
电场
纳米技术
机电学
拓扑缺陷
矢量势
激发极化
作者
Jin Qian,Guanglong Ge,Ziming Cai,Luomeng Tang,Simin Wang,Fei Yan,Bo Shen,Zhenxiang Cheng,Jiwei Zhai
标识
DOI:10.1002/adma.202518813
摘要
Abstract Overcoming the polarization‐relaxor trade‐off in dielectric capacitors remains a critical challenge for achieving simultaneous high energy density ( W rec ) and efficiency ( η ). While conventional polar nano‐regions (PNRs) enhance relaxor behavior, their limited dipole vector lengths inevitably suppress polarization strength. Here, the long‐standing dilemma is resolved by constructing topological vortex domains (VDs) within PNRs (VPNR) through synergistic disorder engineering and grain size confinement in BiFeO 3 ‐based thin films. Phase‐field simulations reveal that the VPNR structure combines ultralow domain‐switching energy barriers with minimally reduced polarization vectors under high electric fields, enabling concurrent optimization of relaxor dynamics and polarization strength. Experimental validations via multiscale characterization confirm that the engineered VPNR configuration exhibits balanced polarization characteristics of high maximum polarization and small remanent polarization. The optimized film achieves a breakthrough W rec of 130 J cm −3 and η of 80% at 4864 kV cm −1 , surpassing pristine BiFeO 3 by 545% and 400%, respectively. This work establishes a topology‐driven paradigm for dielectric energy storage, demonstrating universal potential to decouple polarization‐relaxor constraints in next‐generation capacitive materials.
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