神经形态工程学
铁电性
材料科学
极化(电化学)
非易失性存储器
光电子学
磁滞
薄膜
外延
能量(信号处理)
领域(数学)
铁电电容器
领域(数学分析)
记忆电阻器
电子工程
纳米技术
凝聚态物理
随机存取存储器
负阻抗变换器
切换时间
电压
作者
Jinyang Li,SuZhen Liu,Tao Wang,Zhihe Ren,Cheng Gao,Fenghui Gong,Xiaodong Lv,Chen Su,Sarup Das,Hao Pan,Yunlong Tang,Zuhuang Chen
标识
DOI:10.1002/adma.202521967
摘要
ABSTRACT Multistate non‐volatile ferroelectric memories are promising for in‐memory and neuromorphic computing owing to their high speed and low power operation. Yet, overcoming the intrinsic bi‐stability of ferroelectric switching to reliably achieve multiple polarization states remains a major challenge. Here, we demonstrate robust multi‐level polarization states—exhibiting antiferroelectric‐like hysteresis loops—through selective domain switching in compositionally graded BiFeO 3 –BaTiO 3 epitaxial thin films. These films display well‐separated switching fields and large polarization contrast between adjacent states (Δ P > 40 µC/cm 2 ). Our systematic studies further revealed that the multistate behaviour is attributed to the pinning of ferroelectric domains by oppositely aligned defect dipoles, whose configuration is strongly correlated with the compositional gradient. By engineering this gradient, we effectively tune the internal field and reshape the ferroelectric hysteresis, enabling deterministic control over multiple stable states. This study introduces a new strategy for tailoring ferroelectric energy landscapes, paving the way for high‐density, low‐power, and adaptive ferroelectric memory and neuromorphic architectures.
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