材料科学
反铁电性
兴奋剂
X射线光电子能谱
电场
正电子湮没谱学
电子顺磁共振
光电子学
空位缺陷
陶瓷
密度泛函理论
光谱学
凝聚态物理
分析化学(期刊)
储能
电子
极化(电化学)
相(物质)
电子能量损失谱
原子轨道
晶界
介电常数
分子物理学
高-κ电介质
宽禁带半导体
电介质
作者
G. L. Song,Qing Pan,Xin Zhang,Q. Li,Xinlei Zhang,Jian Su,Zema Chu,Tianyu Li,N. Zhang
摘要
In this work, relaxor antiferroelectric (1−x) AgNbO3−xBiMnO3 ceramics were synthesized by solid-state processing. The analysis of electron paramagnetic resonance and x-ray photoelectron spectroscopy confirmed the coexistence of Mn2+ and Mn3+ states. Positron annihilation lifetime measurements revealed that BiMnO3 doping promoted the formation of cation vacancies VAg′, while effectively suppressing oxygen vacancy VO·· concentration. The resultant reduction in the tolerance factor stabilized the antiferroelectric phase at room temperature. Simultaneously, hybridization between the 6s of Bi3+ and the 2p orbitals of O2− and the generation of VAg′ enhanced the maximum polarization from 39.97 μC/cm2 in undoped AgNbO3 to 62.89 μC/cm2 in the 0.995AgNbO3-0.005BiMnO3 composition. Furthermore, the incorporation of BiMnO3 led to decreased grain size and enhanced breakdown strength. Specifically, the 0.5 mol. % BiMnO3-modified AgNbO3 ceramic achieved a recoverable energy density of 6.87 J/cm3 and a recoverable energy storage intensity of 26.02 × 10−3 J kV−1 cm−2 under a moderate electric field of 264 kV/cm, demonstrating its potential for environmentally compatible energy storage applications.
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