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38 results on '"Zhu, Zengtai"'

1. Anomalous anisotropy of spin current in a cubic spin source with noncollinear antiferromagnetism

Author

Cao, Cuimei, Chen, Shiwei, Xiao, Rui-Chun, Zhu, Zengtai, Yu, Guoqiang, Wang, Yangping, Qiu, Xuepeng, Liu, Liang, Zhao, Tieyang, Shao, Ding-Fu, Xu, Yang, Chen, Jingsheng, and Zhan, Qingfeng

Subjects
Condensed Matter - Materials Science
Abstract

Cubic materials host high crystal symmetry and hence are not expected to support anisotropy in transport phenomena. In contrast to this common expectation, here we report an anomalous anisotropy of spin current can emerge in the (001) film of Mn${_3}$Pt, a noncollinear antiferromagnetic spin source with face-centered cubic structure. Such spin current anisotropy originates from the intertwined time reversal-odd ($T$-odd) and time reversal-even ($T$-even) spin Hall effects. Based on symmetry analyses and experimental characterizations of the current-induced spin torques in Mn${_3}$Pt-based heterostructures, we find that the spin current generated by Mn${_3}$Pt (001) exhibits exotic dependences on the current direction for all the spin components, deviating from that in conventional cubic systems. We also demonstrate that such an anisotropic spin current can be used to realize low-power spintronic applications such as the efficient field-free switching of the perpendicular magnetizations., Comment: 17 pages, 4 figures

Published
2022

4. Direct and Inverse Spin Splitting Effects in Altermagnetic RuO2

Author

Guo, Yaqin, primary, Zhang, Jing, additional, Zhu, Zengtai, additional, Jiang, Yuan‐yuan, additional, Jiang, Longxing, additional, Wu, Chuangwen, additional, Dong, Jing, additional, Xu, Xing, additional, He, Wenqing, additional, He, Bin, additional, Huang, Zhiheng, additional, Du, Luojun, additional, Zhang, Guangyu, additional, Wu, Kehui, additional, Han, Xiufeng, additional, Shao, Ding‐fu, additional, Yu, Guoqiang, additional, and Wu, Hao, additional

Published
2024
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6. Direct and Inverse Spin Splitting Effects in Altermagnetic RuO2.

Author

Guo, Yaqin, Zhang, Jing, Zhu, Zengtai, Jiang, Yuan‐yuan, Jiang, Longxing, Wu, Chuangwen, Dong, Jing, Xu, Xing, He, Wenqing, He, Bin, Huang, Zhiheng, Du, Luojun, Zhang, Guangyu, Wu, Kehui, Han, Xiufeng, Shao, Ding‐fu, Yu, Guoqiang, and Wu, Hao

Subjects
FERROMAGNETIC resonance, SPIN polarization, ELECTRIC currents, ANISOTROPIC crystals, TORQUE
Abstract

Recently, the altermagnetic materials with spin splitting effect (SSE), have drawn significant attention due to their potential to the flexible control of the spin polarization by the Néel vector. Here, the direct and inverse altermagnetic SSE (ASSE) in the (101)‐oriented RuO2 film with the tilted Néel vector are reported. First, the spin torque along the x‐, y‐, and z‐axis is detected from the spin torque‐induced ferromagnetic resonance (ST‐FMR), and the z‐spin torque emerges when the electric current is along the [010] direction, showing the anisotropic spin splitting of RuO2. Further, the current‐induced modulation of damping is used to quantify the damping‐like torque efficiency (ξDL) in RuO2/Py, and an anisotropic ξDL is obtained and maximized for the current along the [010] direction, which increases with the reduction of the temperature, indicating the present of ASSE. Next, by way of spin pumping measurement, the inverse altermagnetic spin splitting effect (IASSE) is studied, which also shows a crystal direction‐dependent anisotropic behavior and temperature‐dependent behavior. This work gives a comprehensive study of the direct and inverse ASSE effects in the altermagnetic RuO2, inspiring future altermagnetic materials and devices with flexible control of spin polarization. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Fermi-Level-Dependent Charge-to-Spin Conversion of the Two-Dimensional Electron Gas at the γ - Al2O3/KTaO3 Interface

Author

Zhang, Hui, primary, Zhu, Zengtai, additional, Zhu, Yungu, additional, Chen, Xiaobing, additional, Jiang, Qisheng, additional, Wei, Jinwu, additional, Zhao, Chenbo, additional, Zhang, Jine, additional, Han, Furong, additional, Yang, Huaiwen, additional, Zhu, Dapeng, additional, Wu, Hao, additional, Chen, Yuansha, additional, Hu, Fengxia, additional, Shen, Baogen, additional, Zhao, Weisheng, additional, Zhang, Jing, additional, Yu, Guoqiang, additional, and Sun, Jirong, additional

Published
2023
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12. Perpendicular Magnetization Switching Driven by Spin‐Orbit Torque for Artificial Synapses in Epitaxial Pt‐Based Multilayers

Author

Zhang, Qiqi, primary, Zhao, Yunchi, additional, He, Congli, additional, Huo, Yuping, additional, Cui, Baoshan, additional, Zhu, Zengtai, additional, Zhang, Guangyu, additional, Yu, Guoqiang, additional, He, Bin, additional, Zhang, Yi, additional, Lyu, Haochang, additional, Guo, Yaqin, additional, Qi, Jie, additional, Shen, Shipeng, additional, Wei, Hongxiang, additional, Shen, Baogen, additional, and Wang, Shouguo, additional

Published
2022
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16. Comprehensive Study of the Current-Induced Spin–Orbit Torque Perpendicular Effective Field in Asymmetric Multilayers

Author

Cui, Baoshan, primary, Zhu, Zengtai, additional, Wu, Chuangwen, additional, Guo, Xiaobin, additional, Nie, Zhuyang, additional, Wu, Hao, additional, Guo, Tengyu, additional, Chen, Peng, additional, Zheng, Dongfeng, additional, Yu, Tian, additional, Xi, Li, additional, Zeng, Zhongming, additional, Liang, Shiheng, additional, Zhang, Guangyu, additional, Yu, Guoqiang, additional, and Wang, Kang L., additional

Published
2022
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17. Néel‐Type Elliptical Skyrmions in a Laterally Asymmetric Magnetic Multilayer

Author

Cui, Baoshan, primary, Yu, Dongxing, additional, Shao, Ziji, additional, Liu, Yizhou, additional, Wu, Hao, additional, Nan, Pengfei, additional, Zhu, Zengtai, additional, Wu, Chuangwen, additional, Guo, Tengyu, additional, Chen, Peng, additional, Zhou, Heng‐An, additional, Xi, Li, additional, Jiang, Wanjun, additional, Wang, Hao, additional, Liang, Shiheng, additional, Du, Haifeng, additional, Wang, Kang L., additional, Wang, Wenhong, additional, Wu, Kehui, additional, Han, Xiufeng, additional, Zhang, Guangyu, additional, Yang, Hongxin, additional, and Yu, Guoqiang, additional

Published
2021
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20. Influence of NiZn-Ferrite Spacers on Giant Magnetoimpedance Effect in FeNi/Cu/FeNi Nano Films

Author

Sun Xiaojun, DU Jinlu, Zhu Zengtai, Liu Qing-Fang, and Wang Jianbo

Subjects
Materials science, Nano, Biomedical Engineering, Ferrite (magnet), General Materials Science, Bioengineering, Nanometre, Giant magnetoimpedance, General Chemistry, Radio frequency magnetron sputtering, Composite material, Condensed Matter Physics, Microstructure
Abstract

FeNi/Cu/FeNi sandwich films without and with one or two NiZn-ferrite spacers were prepared by radio frequency magnetron sputtering. The microstructures and magnetic properties of these multilayer films are presented, and the influence of NiZn-ferrite spacers on the giant magnetoimpedance effect has also been studied. An enhanced giant magnetoimpedance effect is observed in the multilayer film with one 65 nm NiZn-ferrite spacer. The highest giant magnetoimpedance ratio in the FeNi/NiZn-ferrite/Cu/FeNi multilayer film reaches up to 36% at 10 MHz, which is a relatively high value for a nanometer thick film. This ratio is about 1.25 times larger than that of the FeNi/Cu/FeNi sandwich film (similar to 16% at 30 MHz), while the giant magnetoimpedance effect is not evidently enhanced in the FeNi/NiZn-ferrite/Cu/NiZn-ferrite/FeNi multilayer film. These results indicate that inserting one NiZn-ferrite spacer to a sandwich film is a simple and effective way to improve the giant magnetoimpedance effect in the nano film system.

Published
2016

21. Voltage-Driven Nonlinearity in Magnetoelectric Heterostructures

Author

Chu, Zhaoqiang, primary, Dong, Cunzheng, additional, Tu, Cheng, additional, He, Yifan, additional, Liang, Xianfeng, additional, Wang, Jiawei, additional, Wei, Yuyi, additional, Chen, Huaihao, additional, Gao, Xiangyu, additional, Lu, Caijiang, additional, Zhu, Zengtai, additional, Lin, Yuanhua, additional, Dong, Shuxiang, additional, McCord, Jeffrey, additional, and Sun, Nian-Xiang, additional

Published
2019
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28. Direct and Inverse Spin Splitting Effects in Altermagnetic RuO2.

Author

Guo, Yaqin, Zhang, Jing, Zhu, Zengtai, Jiang, Yuan‐yuan, Jiang, Longxing, Wu, Chuangwen, Dong, Jing, Xu, Xing, He, Wenqing, He, Bin, Huang, Zhiheng, Du, Luojun, Zhang, Guangyu, Wu, Kehui, Han, Xiufeng, Shao, Ding‐fu, Yu, Guoqiang, and Wu, Hao

Subjects
*FERROMAGNETIC resonance, *SPIN polarization, *ELECTRIC currents, *ANISOTROPIC crystals, *TORQUE
Abstract

Recently, the altermagnetic materials with spin splitting effect (SSE), have drawn significant attention due to their potential to the flexible control of the spin polarization by the Néel vector. Here, the direct and inverse altermagnetic SSE (ASSE) in the (101)‐oriented RuO2 film with the tilted Néel vector are reported. First, the spin torque along the x‐, y‐, and z‐axis is detected from the spin torque‐induced ferromagnetic resonance (ST‐FMR), and the z‐spin torque emerges when the electric current is along the [010] direction, showing the anisotropic spin splitting of RuO2. Further, the current‐induced modulation of damping is used to quantify the damping‐like torque efficiency (ξDL) in RuO2/Py, and an anisotropic ξDL is obtained and maximized for the current along the [010] direction, which increases with the reduction of the temperature, indicating the present of ASSE. Next, by way of spin pumping measurement, the inverse altermagnetic spin splitting effect (IASSE) is studied, which also shows a crystal direction‐dependent anisotropic behavior and temperature‐dependent behavior. This work gives a comprehensive study of the direct and inverse ASSE effects in the altermagnetic RuO2, inspiring future altermagnetic materials and devices with flexible control of spin polarization. [ABSTRACT FROM AUTHOR]

Published
2024
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