材料科学
位错
电介质
压电
钛酸钡
凝聚态物理
磁畴壁(磁性)
各向异性
衍射
透射电子显微镜
铁电性
介电常数
光学
纳米技术
光电子学
复合材料
磁场
物理
磁化
量子力学
作者
Fangping Zhuo,Xiandong Zhou,Shuang Gao,Marion Höfling,Felix Dietrich,Pedro B. Groszewicz,Lovro Fulanović,Patrick Breckner,Andreas Wohninsland,Bai‐Xiang Xu,Hans‐Joachim Kleebe,Xiaoli Tan,Jurij Koruza,Dragan Damjanović,Jürgen Rödel
标识
DOI:10.1038/s41467-022-34304-7
摘要
Dislocations are usually expected to degrade electrical, thermal and optical functionality and to tune mechanical properties of materials. Here, we demonstrate a general framework for the control of dislocation-domain wall interactions in ferroics, employing an imprinted dislocation network. Anisotropic dielectric and electromechanical properties are engineered in barium titanate crystals via well-controlled line-plane relationships, culminating in extraordinary and stable large-signal dielectric permittivity (≈23100) and piezoelectric coefficient (≈2470 pm V-1). In contrast, a related increase in properties utilizing point-plane relation prompts a dramatic cyclic degradation. Observed dielectric and piezoelectric properties are rationalized using transmission electron microscopy and time- and cycle-dependent nuclear magnetic resonance paired with X-ray diffraction. Succinct mechanistic understanding is provided by phase-field simulations and driving force calculations of the described dislocation-domain wall interactions. Our 1D-2D defect approach offers a fertile ground for tailoring functionality in a wide range of functional material systems.
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