Dynamic Structure Evolution under Invariant Lattice Framework in Fluorite-Type Ferroelectrics

Yunzhe Zheng; Heng Yu; Tianjiao Xin; Kan Hao Xue; Yilin Xu; Zhaomeng Gao; Cheng Liu; Qiwendong Zhao; Yonghui Zheng; Xiangshui Miao; Yan Cheng

doi:10.1021/acs.nanolett.5c03512

Dynamic Structure Evolution under Invariant Lattice Framework in Fluorite-Type Ferroelectrics

Yunzhe Zheng
, Heng Yu
, Tianjiao Xin
, Kan Hao Xue^*
, Yilin Xu
, Zhaomeng Gao
, Cheng Liu
, Qiwendong Zhao
, Yonghui Zheng
, Xiangshui Miao
, Yan Cheng^*

^*此作品的通讯作者

物理与电子科学学院

East China Normal University
Huazhong University of Science and Technology
Chinese Academy of Sciences

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

Insightful design of HfO₂-based ferroelectric (FE) devices for encoding and storage necessitates a comprehensive understanding of the dynamics governing structure evolution. However, conclusive experimental evidence remains limited. Here, by in situ biasing directly on the TiN/Hf_0.5Zr_0.5O₂/TiN FE capacitors and combining theoretical calculations, we reveal the atomic-scale domain structure evolution via a transient polar orthorhombic (O)-Pmn2₁-like configuration. Direct atomic evidence demonstrates that the antipolar O-Pbca phase could transform into the FE O-Pbc2₁phase under electric fields, and the polar axis of the FE phase aligns toward the bias direction through a ferroelastic transformation, thereby enhancing FE polarization. As the bias increases, the polar axis collapses, leading to FE degradation. Throughout the process of domain structure evolution, the lattice framework retains its integrity without alteration. These insights into the intricate structure evolution under electrical field cycling facilitate optimization and design strategies for HfO₂-based FE memory devices.

源语言	英语
页（从-至）	14913-14919
页数	7
期刊	Nano Letters
卷	25
期	41
DOI	https://doi.org/10.1021/acs.nanolett.5c03512
出版状态	已出版 - 15 10月 2025

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title = "Dynamic Structure Evolution under Invariant Lattice Framework in Fluorite-Type Ferroelectrics",

abstract = "Insightful design of HfO2-based ferroelectric (FE) devices for encoding and storage necessitates a comprehensive understanding of the dynamics governing structure evolution. However, conclusive experimental evidence remains limited. Here, by in situ biasing directly on the TiN/Hf0.5Zr0.5O2/TiN FE capacitors and combining theoretical calculations, we reveal the atomic-scale domain structure evolution via a transient polar orthorhombic (O)-Pmn21-like configuration. Direct atomic evidence demonstrates that the antipolar O-Pbca phase could transform into the FE O-Pbc21phase under electric fields, and the polar axis of the FE phase aligns toward the bias direction through a ferroelastic transformation, thereby enhancing FE polarization. As the bias increases, the polar axis collapses, leading to FE degradation. Throughout the process of domain structure evolution, the lattice framework retains its integrity without alteration. These insights into the intricate structure evolution under electrical field cycling facilitate optimization and design strategies for HfO2-based FE memory devices.",

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AU - Zheng, Yunzhe

AU - Yu, Heng

AU - Xin, Tianjiao

AU - Xue, Kan Hao

AU - Xu, Yilin

AU - Gao, Zhaomeng

AU - Liu, Cheng

AU - Zhao, Qiwendong

AU - Zheng, Yonghui

AU - Miao, Xiangshui

AU - Cheng, Yan

PY - 2025/10/15

Y1 - 2025/10/15

N2 - Insightful design of HfO2-based ferroelectric (FE) devices for encoding and storage necessitates a comprehensive understanding of the dynamics governing structure evolution. However, conclusive experimental evidence remains limited. Here, by in situ biasing directly on the TiN/Hf0.5Zr0.5O2/TiN FE capacitors and combining theoretical calculations, we reveal the atomic-scale domain structure evolution via a transient polar orthorhombic (O)-Pmn21-like configuration. Direct atomic evidence demonstrates that the antipolar O-Pbca phase could transform into the FE O-Pbc21phase under electric fields, and the polar axis of the FE phase aligns toward the bias direction through a ferroelastic transformation, thereby enhancing FE polarization. As the bias increases, the polar axis collapses, leading to FE degradation. Throughout the process of domain structure evolution, the lattice framework retains its integrity without alteration. These insights into the intricate structure evolution under electrical field cycling facilitate optimization and design strategies for HfO2-based FE memory devices.

AB - Insightful design of HfO2-based ferroelectric (FE) devices for encoding and storage necessitates a comprehensive understanding of the dynamics governing structure evolution. However, conclusive experimental evidence remains limited. Here, by in situ biasing directly on the TiN/Hf0.5Zr0.5O2/TiN FE capacitors and combining theoretical calculations, we reveal the atomic-scale domain structure evolution via a transient polar orthorhombic (O)-Pmn21-like configuration. Direct atomic evidence demonstrates that the antipolar O-Pbca phase could transform into the FE O-Pbc21phase under electric fields, and the polar axis of the FE phase aligns toward the bias direction through a ferroelastic transformation, thereby enhancing FE polarization. As the bias increases, the polar axis collapses, leading to FE degradation. Throughout the process of domain structure evolution, the lattice framework retains its integrity without alteration. These insights into the intricate structure evolution under electrical field cycling facilitate optimization and design strategies for HfO2-based FE memory devices.

KW - ferroelectricity

KW - hafnium zirconium oxide

KW - in situ transmission electron microscope

KW - structure evolution

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M3 - 文章

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SN - 1530-6984

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EP - 14919

JO - Nano Letters

JF - Nano Letters

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ER -

Dynamic Structure Evolution under Invariant Lattice Framework in Fluorite-Type Ferroelectrics

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