Deterministic, Reversible, and Nonvolatile Low-Voltage Writing of Magnetic Domains in Epitaxial BaTiO3/Fe3O4 Heterostructure

Zhong Gaokuo; An Feng; Bitla Yugandhar; Wang Jinbin; Zhong Xiangli; Yu Junxi; Gao Wenpei; Zhang Yi; Tang Congbing; Ou Yun; Jiang Jie; Hsieh Ying-Hui; Pan Xiaoqing; Xie Shuhong; Chu Ying-Hao; Li Jiangyu

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Deterministic, Reversible, and Nonvolatile Low-Voltage Writing of Magnetic Domains in Epitaxial BaTiO3/Fe3O4 Heterostructure

机译：外延BATIO3 / FE3O4异质结构磁性结构域的确定性，可逆和非易失性低压写入

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The ability to electrically write magnetic bits is highly desirable for future magnetic memories and spintronic devices, though fully deterministic, reversible, and nonvolatile switching of magnetic moments by electric field remains elusive despite extensive research. In this work, we develop a concept to electrically switch magnetization via polarization modulated oxygen vacancies, and we demonstrate the idea in a multiferroic epitaxial heterostructure of BaTiO3/Fe3O4 fabricated by pulsed laser deposition. The piezoelectricity and ferroelectricity of BaTiO3 have been confirmed by macro- and microscale measurements, for which Fe(3)O(4 )serves as the top electrode for switching the polarization. X-ray absorption spectroscopy and X-ray magnetic circular dichroism spectra indicate a mixture of Fe2+ and Fe3+ at O-h sites and Fe3+ at T-d sites in Fe3O4, while the room-temperature magnetic domains of Fe3O4 are revealed by microscopic magnetic force microscopy measurements. It is demonstrated that the magnetic domains of Fe(3)O(4 )can be switched by not only magnetic fields but also electric fields in a deterministic, reversible, and nonvolatile manner, wherein polarization reversal by electric field modulates the oxygen vacancy distribution in Fe3O4, and thus its magnetic state, making it attractive for electrically written magnetic memories.

机译：对于未来的磁存储器和旋转性装置来说，对于未来的磁气记忆和施工装置来说，对于未来的磁场，可逆的和非易失性，磁场的完全确定性，可逆的和非易失性切换，尽管研究仍然是难以捉摸的，但尽管进行了广泛的研究，但是磁场仍然难以实现。在这项工作中，我们通过偏振调制的氧空位开发一个概念以电动切换磁化，并且我们在由脉冲激光沉积制造的BATIO3 / Fe3O4的多二二种外延异质结构中展示了该思想。 BATIO3的压电和铁电性通过宏观和微尺度测量证实，Fe（3）O（4）用作用于切换极化的顶部电极。 X射线吸收光谱和X射线磁性圆形二色性光谱表示Fe3O4的O-H位点和Fe3 +在Fe3O4的T-D位点的Fe2 +和Fe3 +的混合物，而通过显微磁力显微镜测量揭示Fe3O4的室温磁性结构域。结果证明Fe（3）O（4）的磁畴不仅可以通过磁场而切换，而且可以在确定性，可逆和非易失性的方式中切换电场，其中通过电场的偏振反转调节氧空位分布Fe3O4，因此是其磁力状态，使其对电写磁存储器具有吸引力。

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来源
《ACS nano》 |2018年第9期|共10页
作者
Zhong Gaokuo; An Feng; Bitla Yugandhar; Wang Jinbin; Zhong Xiangli; Yu Junxi; Gao Wenpei; Zhang Yi; Tang Congbing; Ou Yun; Jiang Jie; Hsieh Ying-Hui; Pan Xiaoqing; Xie Shuhong; Chu Ying-Hao; Li Jiangyu;
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作者单位

Chinese Acad Sci Shenzhen Inst Adv Technol Shenzhen Key Lab Nanobiomech Shenzhen 518055 Guangdong Peoples R China;

Xiangtan Univ Minist Educ Key Lab Low Dimens Mat &

Applicat Technol Xiangtan 411105 Hunan Peoples R China;

Indian Inst Sci Dept Phys Bengaluru 560012 India;

Xiangtan Univ Minist Educ Key Lab Low Dimens Mat &

Applicat Technol Xiangtan 411105 Hunan Peoples R China;

Xiangtan Univ Minist Educ Key Lab Low Dimens Mat &

Applicat Technol Xiangtan 411105 Hunan Peoples R China;

Chinese Acad Sci Shenzhen Inst Adv Technol Shenzhen Key Lab Nanobiomech Shenzhen 518055 Guangdong Peoples R China;

Univ Calif Irvine Dept Chem Engn &

Mat Sci Irvine CA 92697 USA;

Univ Calif Irvine Dept Chem Engn &

Mat Sci Irvine CA 92697 USA;

Xiangtan Univ Minist Educ Key Lab Low Dimens Mat &

Applicat Technol Xiangtan 411105 Hunan Peoples R China;

Chinese Acad Sci Shenzhen Inst Adv Technol Shenzhen Key Lab Nanobiomech Shenzhen 518055 Guangdong Peoples R China;

Xiangtan Univ Minist Educ Key Lab Low Dimens Mat &

Applicat Technol Xiangtan 411105 Hunan Peoples R China;

Natl Chiao Tung Univ Dept Mat Sci &

Engn Hsinchu 30010 Taiwan;

Univ Calif Irvine Dept Chem Engn &

Mat Sci Irvine CA 92697 USA;

Xiangtan Univ Minist Educ Key Lab Low Dimens Mat &

Applicat Technol Xiangtan 411105 Hunan Peoples R China;

Natl Chiao Tung Univ Dept Mat Sci &

Engn Hsinchu 30010 Taiwan;

Chinese Acad Sci Shenzhen Inst Adv Technol Shenzhen Key Lab Nanobiomech Shenzhen 518055 Guangdong Peoples R China;

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原文格式 PDF
正文语种 eng
中图分类分子物理学、原子物理学;
关键词
multiferroic heterostructure; magnetoelectric coupling; Fe3O4; low-voltage writing; oxygen vacancies;

机译：多体异质结构;磁电耦合;FE3O4;低压写入;氧气职位空缺;

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专利

1. Deterministic, Reversible, and Nonvolatile Low-Voltage Writing of Magnetic Domains in Epitaxial BaTiO3/Fe3O4 Heterostructure [J] . Zhong Gaokuo, An Feng, Bitla Yugandhar, ACS nano . 2018,第9期

机译：外延BATIO3 / FE3O4异质结构磁性结构域的确定性，可逆和非易失性低压写入
2. Electrical Writing of Magnetic Domain Patterns in Ferromagnetic/Ferroelectric Heterostructures [J] . Lahtinen T. H. E., Tuomi J. O., van Dijken S. Magnetics, IEEE Transactions on . 2011,第10期

机译：铁磁/铁电异质结构中磁畴图形的电写入
3. Layer resolved magnetic domain imaging of epitaxial heterostructures in large applied magnetic fields [J] . S. Zohar, Y. Choi, D. M. Love, Applied Physics Letters . 2015,第7期

机译：大磁场作用下外延异质结构的层分辨磁畴成像
4. Nonvolatile, reversible writing of electronic nanostructures in epitaxial ferroelectric/metallic oxide heterostructures using a field effect [C] . C.H. Ahn, T. Tybell, L. Antognazza, Symposium on ferroelectric thin films . 1998

机译：使用田间效应的外延铁电/金属氧化物异质结构中电子纳米结构的非易失性写入
5. Deterministic and Robust Room-Temperature Exchange Coupling in Monodomain Multiferroic BiFeO3/Co Heterostructures. [D] . Saenrang, Wittawat. 2015

机译：单畴多铁性BiFeO3 / Co异质结构中的确定性和鲁棒的室温交换耦合。
6. Monolithic integration of room-temperature multifunctional BaTiO3-CoFe2O4 epitaxial heterostructures on Si(001) [O] . Mateusz Scigaj, Nico Dix, Jaume Gázquez, -1

机译：Si（001）上室温多功能BaTiO3-CoFe2O4外延异质结构的整体集成
7. Magnetic anisotropy modulation of magnetite in Fe3O4/BaTiO3(100) epitaxial structures [O] . Vaz, C. A. F., Hoffman, J., Posadas, A. -B., 2008

机译：Fe3O4 / BaTiO3（100）中磁铁矿的磁各向异性调制外延结构

Deterministic, Reversible, and Nonvolatile Low-Voltage Writing of Magnetic Domains in Epitaxial BaTiO3/Fe3O4 Heterostructure

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