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243 results on '"Gao, Xingsen"'

1. NAFRSSR: a Lightweight Recursive Network for Efficient Stereo Image Super-Resolution

Author

Chen, Yihong, Fan, Zhen, Dong, Shuai, Chen, Zhiwei, Li, Wenjie, Qin, Minghui, Zeng, Min, Lu, Xubing, Zhou, Guofu, Gao, Xingsen, and Liu, Jun-Ming

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition
Abstract

Stereo image super-resolution (SR) refers to the reconstruction of a high-resolution (HR) image from a pair of low-resolution (LR) images as typically captured by a dual-camera device. To enhance the quality of SR images, most previous studies focused on increasing the number and size of feature maps and introducing complex and computationally intensive structures, resulting in models with high computational complexity. Here, we propose a simple yet efficient stereo image SR model called NAFRSSR, which is modified from the previous state-of-the-art model NAFSSR by introducing recursive connections and lightweighting the constituent modules. Our NAFRSSR model is composed of nonlinear activation free and group convolution-based blocks (NAFGCBlocks) and depth-separated stereo cross attention modules (DSSCAMs). The NAFGCBlock improves feature extraction and reduces number of parameters by removing the simple channel attention mechanism from NAFBlock and using group convolution. The DSSCAM enhances feature fusion and reduces number of parameters by replacing 1x1 pointwise convolution in SCAM with weight-shared 3x3 depthwise convolution. Besides, we propose to incorporate trainable edge detection operator into NAFRSSR to further improve the model performance. Four variants of NAFRSSR with different sizes, namely, NAFRSSR-Mobile (NAFRSSR-M), NAFRSSR-Tiny (NAFRSSR-T), NAFRSSR-Super (NAFRSSR-S) and NAFRSSR-Base (NAFRSSR-B) are designed, and they all exhibit fewer parameters, higher PSNR/SSIM, and faster speed than the previous state-of-the-art models. In particular, to the best of our knowledge, NAFRSSR-M is the lightest (0.28M parameters) and fastest (50 ms inference time) model achieving an average PSNR/SSIM as high as 24.657 dB/0.7622 on the benchmark datasets. Codes and models will be released at https://github.com/JNUChenYiHong/NAFRSSR.

Published
2024

2. Room-temperature sub-100 nm N\'eel-type skyrmions in non-stoichiometric van der Waals ferromagnet $\rm Fe_{3-x}GaTe_{2}$ with ultrafast laser writability

Author

Li, Zefang, Zhang, Huai, Li, Guanqi, Guo, Jiangteng, Wang, Qingping, Deng, Ying, Hu, Yue, Hu, Xuange, Liu, Can, Qin, Minghui, Shen, Xi, Yu, Richeng, Gao, Xingsen, Liao, Zhimin, Liu, Junming, Hou, Zhipeng, Zhu, Yimei, and Fu, Xuewen

Subjects
Condensed Matter - Materials Science
Abstract

Realizing room-temperature magnetic skyrmions in two-dimensional van der Waals ferromagnets offers unparalleled prospects for future spintronic applications. However, due to the intrinsic spin fluctuations that suppress atomic long-range magnetic order and the inherent inversion crystal symmetry that excludes the presence of the Dzyaloshinskii-Moriya interaction, achieving room-temperature skyrmions in 2D magnets remains a formidable challenge. In this study, we target room-temperature 2D magnet $\rm Fe_3GaTe_2$ and unveil that the introduction of iron-deficient into this compound enables spatial inversion symmetry breaking, thus inducing a significant Dzyaloshinskii-Moriya interaction that brings about room-temperature N\'eel-type skyrmions with unprecedentedly small size. To further enhance the practical applications of this finding, we employ a homemade in-situ optical Lorentz transmission electron microscopy to demonstrate ultrafast writing of skyrmions in $\rm Fe_{3-x}GaTe_2$ using a single femtosecond laser pulse. Our results manifest the $\rm Fe_{3-x}GaTe_2$ as a promising building block for realizing skyrmion-based magneto-optical functionalities.

Published
2024
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4. Controllable Skyrmionic Phase Transition between Néel Skyrmions and Bloch Skyrmionic Bubbles in van der Waals Ferromagnet Fe3‐δGeTe2

Author

Liu, Chen, Jiang, Jiawei, Zhang, Chenhui, Wang, Qingping, Zhang, Huai, Zheng, Dongxing, Li, Yan, Ma, Yinchang, Algaidi, Hanin, Gao, Xingsen, Hou, Zhipeng, Mi, Wenbo, Liu, Jun‐ming, Qiu, Ziqiang, and Zhang, Xixiang

Subjects
Quantum Physics, Physical Sciences, 2D ferromagnet Fe3-& delta, GeTe2, Dzyaloshinskii-Moriya interaction, Fe atom displacement, magnetic skyrmions, 2D ferromagnet Fe3-δGeTe2
Abstract

The van der Waals (vdW) ferromagnet Fe3-δ GeTe2 has garnered significant research interest as a platform for skyrmionic spin configurations, that is, skyrmions and skyrmionic bubbles. However, despite extensive efforts, the origin of the Dzyaloshinskii-Moriya interaction (DMI) in Fe3-δ GeTe2 remains elusive, making it challenging to acquire these skyrmionic phases in a controlled manner. In this study, it is demonstrated that the Fe content in Fe3-δ GeTe2 has a profound effect on the crystal structure, DMI, and skyrmionic phase. For the first time, a marked increase in Fe atom displacement with decreasing Fe content is observed, transforming the original centrosymmetric crystal structure into a non-centrosymmetric symmetry, leading to a considerable DMI. Additionally, by varying the Fe content and sample thickness, a controllable transition between Néel-type skyrmions and Bloch-type skyrmionic bubbles is achieved, governed by a delicate interplay between dipole-dipole interaction and the DMI. The findings offer novel insights into the variable skyrmionic phases in Fe3-δ GeTe2 and provide the impetus for developing vdW ferromagnet-based spintronic devices.

Published
2023

5. Tripling energy storage density through order-disorder transition induced polar nanoregions in PbZrO3 thin films by ion implantation

Author

Luo, Yongjian, Wang, Changan, Chen, Chao, Gao, Yuan, Sun, Fei, Li, Caiwen, Yin, Xiaozhe, Luo, Chunlai, Kentsch, Ulrich, Cai, Xiangbin, Bai, Mei, Fan, Zhen, Qin, Minghui, Zeng, Min, Dai, Jiyan, Zhou, Guofu, Lu, Xubing, Lou, Xiaojie, Zhou, Shengqiang, Gao, Xingsen, Chen, Deyang, and Liu, Jun-Ming

Subjects
Condensed Matter - Materials Science
Abstract

Dielectric capacitors are widely used in pulsed power electronic devices due to their ultrahigh power densities and extremely fast charge/discharge speed. To achieve enhanced energy storage density, both maximum polarization (Pmax) and breakdown strength (Eb) need to be improved simultaneously. However, these two key parameters are inversely correlated. In this study, order-disorder transition induced polar nanoregions (PNRs) have been achieved in PbZrO3 thin films by making use of the low-energy ion implantation, enabling us overcome the trade-off between high polarizability and breakdown strength, which leads to the tripling of the energy storage density from 20.5 J/cm3 to 62.3 J/cm3 as well as the great enhancement of breakdown strength. This approach could be extended to other dielectric oxides to improve the energy storage performance, providing a new pathway for tailoring the oxide functionalities.

Published
2022

6. Deterministic manipulation of multi-state polarization switching in multiferroic thin films

Author

Chen, Chao, Chen, Deyang, Li, Peilian, Qin, Minghui, Lu, Xubing, Zhou, Guofu, Gao, Xingsen, and Liu, Jun-Ming

Subjects
Condensed Matter - Materials Science
Abstract

Deterministically controllable multi-state polarizations in ferroelectric materials are promising for the application of next-generation non-volatile multi-state memory devices. However, the achievement of multi-state polarizations has been inhibited by the challenge of selective control of switching pathways. Here we report an approach to selectively control 71{\deg} ferroelastic and 180{\deg} ferroelectric switching paths by combining the out-of-plane electric field and in-plane trailing field in multiferroic BiFeO3 thin films with periodically ordered 71{\deg} domain wall. Four-state polarization states can be deterministically achieved and reversibly controlled through precisely selecting different switching paths. Our studies reveal the ability to obtain multiple polarization states for the realization of multi-state memories and magnetoelectric coupling based devices.

Published
2022

9. Topologically Protected Ferroelectric Domain Wall Memory with Large Readout Current

Author

Yang, Wenda, Tian, Guo, Fan, Hua, Zhao, Yue, Chen, Hongying, Zhang, Luyong, Wang, Yadong, Fan, Zhen, Hou, Zhipeng, Chen, Deyang, Gao, Jinwei, Zeng, Min, Lu, Xubing, Qin, Minghui, Gao, Xingsen, and Liu, Jun-Ming

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

The discovery and precise manipulation of atomic-size conductive ferroelectric domain defects, such as geometrically confined walls, offer new opportunities for a wide range of prospective electronic devices, and the so-called walltronics is emerging consequently. Here we demonstrate the highly stable and fatigue-resistant nonvolatile ferroelectric memory device based on deterministic creation and erasure of conductive domain wall geometrically confined inside a topological domain structure. By introducing a pair of delicately designed co-axial electrodes onto the epitaxial BiFeO3 film, one can easily create quadrant center topological polar domain structure. More importantly, a reversible switching of such center topological domain structure between the convergent state with highly conductive confined wall and the divergent state with insulating confined wall can be realized, hence resulting in an apparent resistance change with a large On/Off ratio > 104 and a technically preferred readout current (up to 40 nA). Owing to the topological robustness of the center domain structure, the device exhibits the excellent restoration repeatability over 106 cycles and a long retention over 12 days (> 106 s). This work demonstrates a good example for implementing the exotic polar topologies in high-performance nanoscale devices, and would spur more interest in exploring the rich emerging applications of these exotic topological states.

Published
2021

14. Electric-field-driven Non-volatile Multi-state Switching of Individual Skyrmions in a Multiferroic Heterostructure

Author

Wang, Yadong, Wang, Lei, Xia, Jing, Lai, Zhengxun, Tian, Guo, Zhang, Xichao, Hou, Zhipeng, Gao, Xingsen, Mi, Wenbo, Feng, Chun, Zeng, Min, Zhou, Guofu, Yu, Guanghua, Wu, Guangheng, Zhou, Yan, Wang, Wenhong, Zhang, Xi-xiang, and Liu, Junming

Subjects
Condensed Matter - Materials Science
Abstract

Electrical manipulation of skyrmions attracts considerable attention for its rich physics and promising applications. To date, such a manipulation is realized mainly via spin-polarized current based on spin-transfer torque or spin-orbital torque effect. However, this scheme is energy-consuming and may produce massive Joule heating. To reduce energy dissipation and risk of heightened temperatures of skyrmion-based devices, an effective solution is to use electric field instead of current as stimulus. Here, we realize an electric-field manipulation of skyrmions in a nanostructured ferromagnetic/ferroelectrical heterostructure at room temperature via an inverse magneto-mechanical effect. Intriguingly, such a manipulation is non-volatile and exhibits a multi-state feature. Numerical simulations indicate that the electric-field manipulation of skyrmions originates from strain-mediated modification of effective magnetic anisotropy and Dzyaloshinskii-Moriya interaction. Our results open a direction for constructing low-energy-dissipation, non-volatile, and multi-state skyrmion-based spintronic devices., Comment: Accepted by Nature Communications 11, 3577 (2020)

Published
2020
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15. Enhanced Stability of Antiferromagnetic Skyrmion during Its Motion by Anisotropic Dzyaloshinskii Moriya Interaction

Author

Huang, Zongpeng, Jin, Zhejunyu, Zhang, Xiaomiao, Hou, Zhipeng, Chen, Deyang, Fan, Zhen, Zeng, Min, Lu, Xubing, Gao, Xingsen, and Qin, Minghui

Subjects
Physics - Applied Physics
Abstract

Searching for new methods to enhance the stability of antiferromagnetic (AFM) skyrmion during its motion is an important issue for AFM spintronic devices. Herein, the spin polarized current-induced dynamics of a distorted AFM skyrmion is numerically studied, based on the Landau Lifshitz Gilbert simulations of the model with an anisotropic Dzyaloshinskii Moriya (DM) interaction. It is demonstrated that the DM interaction anisotropy induces the skyrmion deformation, which suppresses the distortion during the motion and enhances the stability of the skyrmion. Moreover, the effect of the DM interaction anisotropy on the skyrmion velocity is investigated in detail, and the simulated results are further explained by Thiele theory. This work unveils a promising strategy to enhance the stability and the maximum velocity of AFM skyrmion, benefiting future spintronic applications., Comment: 21 Pages, 6 figures

Published
2020
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16. Quasi-one-dimensional metallic conduction channels in exotic ferroelectric topological defects

Author

Yang, Wenda, Tian, Guo, Zhang, Yang, Xue, Fei, Zheng, Dongfeng, Zhang, Luyong, Wang, Yadong, Chen, Chao, Fan, Zhen, Hou, Zhipeng, Chen, Deyang, Gao, Jinwei, Zeng, Min, Qin, Minghui, Chen, Long-Qing, Gao, Xingsen, and Liu, Jun-Ming

Subjects
Condensed Matter - Materials Science
Abstract

Ferroelectric topological objects (e.g. vortices, skyrmions) provide a fertile ground for exploring emerging physical properties that could potentially be utilized in future configurable nanoelectronic devices. Here, we demonstrate quasi-one-dimensional metallic high conduction channels along two types of exotic topological defects, i.e. the topological cores of (i) a quadrant vortex domain structure and (ii) a center domain (monopole-like) structure confined in high quality BiFeO3 nanoisland array, abbreviated as the vortex core and the center core. We unveil via phase-field simulations that the superfine (< 3 nm) metallic conduction channels along center cores arise from the screening charge carriers confined at the core whereas the high conductance of vortex cores results from a field-induced twisted state. These conducting channels can be repeatedly and reversibly created and deleted by manipulating the two topological states via an electric field, leading to an apparent electroresistance effect with an on/off ratio higher than 103. These results open up the possibility of utilizing these functional one-dimensional topological objects in high-density nanoelectronic devices such as ultrahigh density nonvolatile memory., Comment: manuscript (21 pages, 4 figures) plus supplementary information

Published
2020
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17. Topological Hall effect in single thick SrRuO3 layers induced by defect engineering

Author

Wang, Changan, Chang, Ching-Hao, Herklotz, Andreas, Chen, Chao, Ganss, Fabian, Kentsch, Ulrich, Chen, Deyang, Gao, Xingsen, Zeng, Yu-Jia, Hellwig, Olav, Helm, Manfred, Gemming, Sibylle, Chu, Ying-Hao, and Zhou, Shengqiang

Subjects
Condensed Matter - Materials Science
Abstract

The topological Hall effect (THE) has been discovered in ultrathin SrRuO3 (SRO) films, where the interface between the SRO layer and another oxide layer breaks the inversion symmetry resulting in the appearance of THE. Thus, THE only occurs in ultra-thin SRO films of several unit cells. In addition to employing a heterostructure, the inversion symmetry can be broken intrinsically in bulk SRO by introducing defects. In this study THE is observed in 60 nm thick SRO films, in which defects and lattice distortions are introduced by helium ion irradiation. The irradiated SRO films exhibit a pronounced THE in a wide temperature range from 5 K to 80 K. These observations can be attributed to the emergence of Dzyaloshinskii-Moriya interaction as a result of artificial inversion symmetry breaking associated to the lattice defect engineering. The creation and control of the THE in oxide single layers can be realized by ex situ film processing. Therefore, this work provides new insights into the THE and illustrates a promising strategy to design novel spintronics devices., Comment: 18 pages, including the suppl. material, to be published at Advanced Electronic Materials

Published
2020
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19. Strain engineering of epitaxial oxide heterostructures beyond substrate limitations

Author

Deng, Xiong, Chen, Chao, Chen, Deyang, Cai, Xiangbin, Yin, Xiaozhe, Xu, Chao, Sun, Fei, Li, Caiwen, Li, Yan, Xu, Han, Ye, Mao, Tian, Guo, Fan, Zhen, Hou, Zhipeng, Qin, Minghui, Chen, Yu, Luo, Zhenlin, Lu, Xubing, Zhou, Guofu, Chen, Lang, Wang, Ning, Zhu, Ye, Gao, Xingsen, and Liu, Jun-Ming

Subjects
Condensed Matter - Materials Science
Abstract

The limitation of commercially available single-crystal substrates and the lack of continuous strain tunability preclude the ability to take full advantage of strain engineering for further exploring novel properties and exhaustively studying fundamental physics in complex oxides. Here we report an approach for imposing continuously tunable, large epitaxial strain in oxide heterostructures beyond substrate limitations by inserting an interface layer through tailoring its gradual strain relaxation. Taking BiFeO3 as a model system, we demonstrate that the introduction of an ultrathin interface layer allows the creation of a desired strain that can induce phase transition and stabilize a new metastable super-tetragonal phase as well as morphotropic phase boundaries overcoming substrate limitations. Furthermore, continuously tunable strain from tension to compression can be generated by precisely adjusting the thickness of the interface layer, leading to the first achievement of continuous O-R-T phase transition in BiFeO3 on a single substrate. This proposed route could be extended to other oxide heterostructures, providing a platform for creating exotic phases and emergent phenomena.

Published
2019

20. Tuning the metal-insulator transition in epitaxial SrVO3 films by uniaxial strain

Author

Wang, Changan, Zhang, Hongbin, Deepak, Kumar, Chen, 5Chao, Fouchet, Arnaud, Duan, Juanmei, Hilliard, Donovan, Kentsch, Ulrich, Chen, Deyang, Zeng, Min, Gao, Xingsen, Zeng, Yu-Jia, Helm, Manfred, Prellier, Wilfrid, and Zhou, Shengqiang

Subjects
Condensed Matter - Materials Science
Abstract

Understanding of the metal-insulator transition (MIT) in correlated transition-metal oxides is a fascinating topic in condensed matter physics and a precise control of such transitions plays a key role in developing novel electronic devices. Here we report an effective tuning of the MIT in epitaxial SrVO3 (SVO) films by expanding the out-of-plane lattice constant without changing in-plane lattice parameters, through helium ion irradiation. Upon increase of the ion fluence, we observe a MIT with a crossover from metallic to insulating state in SVO films. A combination of transport and magnetoresistance measurements in SVO at low temperatures reveals that the observed MIT is mainly ascribed to electron-electron interactions rather than disorder-induced localization. Moreover, these results are well supported by the combination of density functional theory and dynamical mean field theory (DFT+DMFT) calculations, further confirming the decrease of the bandwidth and the enhanced electron-electron interactions resulting from the expansion of out-of-plane lattice constant. These findings provide new insights into the understanding of MIT in correlated oxides and perspectives for the design of unexpected functional devices based on strongly correlated electrons., Comment: 17 pages, 4 figures,submitted to Phys. Rev. Materials

Published
2019
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21. Controllable Defect Driven Symmetry Change and Domain Structure Evolution in BiFeO3 with Enhanced Tetragonality

Author

Chen, Chao, Wang, Changan, Cai, Xiangbin, Xu, Chao, Li, Caiwen, Zhou, Jingtian, Luo, Zhenlin, Fan, Zhen, Qin, Minghui, Zeng, Min, Lu, Xubing, Yang, Ping, Zhou, Guofu, Gao, Xingsen, Wang, Ning, Zhu, Ye, Zhou, Shengqiang, Chen, Deyang, and Liu, Jun-Ming

Subjects
Condensed Matter - Materials Science
Abstract

Defect engineering has been a powerful tool to enable the creation of exotic phases and the discovery of intriguing phenomena in ferroelectric oxides. However, accurate control the concentration of defects remains a big challenge. In this work, ion implantation, that can provide controllable point defects, allows us the ability to produce a controlled defect-driven true super-tetragonal (T) phase with enhanced tetragonality in ferroelectric BiFeO3 thin films. This point defect engineering is found to drive the phase transition from the as-grown mixed rhombohedral-like (R) and tetragonal-like (MC) phase to true tetragonal (T) symmetry. By further increasing the injected dose of He ion, we demonstrate an enhanced tetragonality super-tetragonal (super-T) phase with the largest c/a ratio (~ 1.3) that has ever been experimentally achieved in BiFeO3. A combination of morphology change and domain evolution further confirm that the mixed R/MC phase structure transforms to the single-domain-state true tetragonal phase. Moreover, the re-emergence of R phase and in-plane stripe nanodomains after heat treatment reveal the memory effect and reversible phase transition. Our findings demonstrate the control of R-Mc-T-super T symmetry changes and the creation of true T phase BiFeO3 with enhanced tetragonality through controllable defect engineering. This work also provides a pathway to generate large tetragonality (or c/a ratio) that could be extended to other ferroelectric material systems (such as PbTiO3, BaTiO3 and HfO2) which may lead to strong polarization enhancement.

Published
2019
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22. Manipulation of Conductive Domain Walls in Confined Ferroelectric Nano-islands

Author

Tian, Guo, Yang, Wenda, Song, Xiao, Zheng, Dongfeng, Zhang, Luyong, Chen, Chao, Li, Peilian, Fan, Hua, Yao, Junxiang, Chen, Deyang, Fan, Zhen, Hou, Zhipeng, Zhang, Zhang, Wu, Sujuan, Zeng, Min, Gao, Xingsen, and Liu, Jun-Ming

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Conductive ferroelectric domain walls--ultra-narrow and configurable conduction paths, have been considered as essential building blocks for future programmable domain wall electronics. For applications in high density devices, it is imperative to explore the conductive domain walls in small confined systems while earlier investigations have hitherto focused on thin films or bulk single crystals, noting that the size-confined effects will certainly modulate seriously the domain structure and wall transport. Here, we demonstrate an observation and manipulation of conductive domain walls confined within small BiFeO3 nano-islands aligned in high density arrays. Using conductive atomic force microscopy (CAFM), we are able to distinctly visualize various types of conductive domain walls, including the head-to-head charged walls (CDWs), zigzag walls (zigzag-DWs), and typical 71{\deg} head-to-tail neutral walls (NDWs). The CDWs exhibit remarkably enhanced metallic conductivity with current of ~ nA order in magnitude and 104 times larger than that inside domains (0.01 ~ 0.1 pA), while the semiconducting NDWs allow also much smaller current ~ 10 pA than the CDWs. The substantially difference in conductivity for dissimilar walls enables additional manipulations of various wall conduction states for individual addressable nano-islands via electrically tuning of their domain structures. A controllable writing of four distinctive states by applying various scanning bias voltages is achieved, offering opportunities for developing multilevel high density memories.

Published
2018
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24. Defect-induced exchange bias in a single SrRuO3 layer

Author

Wang, Changan, Chen, Chao, Chang, Ching-Hao, Tsai, Hsu-Sheng, Pandey, Parul, Xu, Chi, Böttger, Roman, Chen, Deyang, Zeng, Yu-Jia, Gao, Xingsen, Helm, Manfred, and Zhou, Shengqiang

Subjects
Condensed Matter - Materials Science
Abstract

Exchange bias stems from the interaction between different magnetic phases and therefore it generally occurs in magnetic multilayers. Here we present a large exchange bias in a single SrRuO3 layer induced by helium ion irradiation. When the fluence increases, the induced defects not only suppress the magnetization and the Curie temperature, but also drive a metal-insulator transition at a low temperature. In particular, a large exchange bias field up to around 0.36 T can be created by the irradiation. This large exchange bias is related to the coexistence of different magnetic and structural phases that are introduced by embedded defects. Our work demonstrates that spintronic properties in complex oxides can be created and enhanced by applying ion irradiation., Comment: 14 pages, 5 figures

Published
2018
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32. Brownian Motion and Entropic Torque Driven Motion of Domain-Wall in Antiferromagnets

Author

Yan, Zhengren, Chen, Zhiyuan, Qin, Minghui, Lu, Xubing, Gao, Xingsen, and Liu, Junming

Subjects
Physics - Computational Physics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We study the spin dynamics in antiferromagnetic nanowire under an applied temperature gradient using micromagnetic simulations on a classical spin model with a uniaxial anisotropy. The entropic torque driven domain-wall motion and the Brownian motion are discussed in detail, and their competition determines the antiferromagnetic wall motion towards the hotter or colder region. Furthermore, the spin dynamics in an antiferromagnet can be well tuned by the anisotropy and the temperature gradient. Thus, this paper not only strengthens the main conclusions obtained in earlier works [Kim et al., Phys. Rev. B 92, 020402(R) (2015); Selzer et al., Phys. Rev. Lett. 117, 107201 (2016)], but more importantly gives the concrete conditions under which these conclusions apply, respectively. Our results may provide useful information on the antiferromagnetic spintronics for future experiments and storage device design., Comment: 6 pages, 7 figures, published in Physical Review B

Published
2017
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33. High density array of epitaxial BiFeO3 nanodots with robust and reversibly switchable topological domain states

Author

Li, Zhongwen, Wang, Yujia, Tian, Guo, Li, Peilian, Zhao, Lina, Zhang, Fengyuan, Yao, Junxiang, Fan, Hua, Song, Xiao, Chen, Deyang, Fan, Zhen, Qin, Minghui, Zeng, Min, Zhang, Zhang, Lu, Xubing, Hu, Shejun, Lei, Chihou, Zhu, Qingfeng, Li, Jiangyu, Gao, Xingsen, and Liu, Jun-Ming

Subjects
Condensed Matter - Materials Science
Abstract

The exotic topological domains in ferroelectrics and multiferroics have attracted extensive interest in recent years due to their novel functionalities and potential applications in nanoelectronic devices. One of the key challenges for such applications is a realization of robust yet reversibly switchable nanoscale topological domain states with high density, wherein spontaneous topological structures can be individually addressed and controlled. This has been accomplished in our work using high density arrays of epitaxial BiFeO3 (BFO) nanodots with lateral size as small as ~60 nm. We demonstrate various types of spontaneous topological domain structures, including center-convergent domains, center-divergent domains, and double-center domains, which are stable over sufficiently long time yet can be manipulated and reversibly switched by electric field. The formation mechanisms of these topological domain states, assisted by the accumulation of compensating charges on the surface, have also been revealed. These result demonstrated that these reversibly switchable topological domain arrays are promising for applications in high density nanoferroelectric devices such as nonvolatile memories, Comment: 5 figures, 18 pages, plus supplementary materials

Published
2017
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37. Interface Engineering of Domain Structures in BiFeO3 Thin Films

Author

Chen, Deyang, Chen, Zuhuang, He, Qian, Clarkson, James D, Serrao, Claudy R, Yadav, Ajay K, Nowakowski, Mark E, Fan, Zhen, You, Long, Gao, Xingsen, Zeng, Dechang, Chen, Lang, Borisevich, Albina Y, Salahuddin, Sayeef, Liu, Jun-Ming, and Bokor, Jeffrey

Subjects
Macromolecular and Materials Chemistry, Engineering, Chemical Sciences, Physical Sciences, BiFeO3, multiferroic, depolarization field, domain wall, exchange bias, superlattices, Nanoscience & Nanotechnology
Abstract

A wealth of fascinating phenomena have been discovered at the BiFeO3 domain walls, examples such as domain wall conductivity, photovoltaic effects, and magnetoelectric coupling. Thus, the ability to precisely control the domain structures and accurately study their switching behaviors is critical to realize the next generation of novel devices based on domain wall functionalities. In this work, the introduction of a dielectric layer leads to the tunability of the depolarization field both in the multilayers and superlattices, which provides a novel approach to control the domain patterns of BiFeO3 films. Moreover, we are able to study the switching behavior of the first time obtained periodic 109° stripe domains with a thick bottom electrode. Besides, the precise controlling of pure 71° and 109° periodic stripe domain walls enable us to make a clear demonstration that the exchange bias in the ferromagnet/BiFeO3 system originates from 109° domain walls. Our findings provide future directions to study the room temperature electric field control of exchange bias and open a new pathway to explore the room temperature multiferroic vortices in the BiFeO3 system.

Published
2017

41. Room-temperature sub-100 nm Néel-type skyrmions in non-stoichiometric van der Waals ferromagnet Fe3-xGaTe2 with ultrafast laser writability

Author

Li, Zefang, primary, Zhang, Huai, additional, Li, Guanqi, additional, Guo, Jiangteng, additional, Wang, Qingping, additional, Deng, Ying, additional, Hu, Yue, additional, Hu, Xuange, additional, Liu, Can, additional, Qin, Minghui, additional, Shen, Xi, additional, Yu, Richeng, additional, Gao, Xingsen, additional, Liao, Zhimin, additional, Liu, Junming, additional, Hou, Zhipeng, additional, Zhu, Yimei, additional, and Fu, Xuewen, additional

Published
2024
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48. The competing spin orders and fractional magnetization plateaus of classical Heisenberg model on Shastry-Sutherland lattice: Consequence of long-range interactions

Author

Huo, Liu, Huang, Weichuan, Yan, Zhibo, Jia, Xingtao, Gao, Xingsen, Qin, Minghui, and Liu, Junming

Subjects
Condensed Matter - Strongly Correlated Electrons, Physics - Classical Physics
Abstract

The competing spin orders and fractional magnetization plateaus of classical Heisenberg model with long-range interactions on a Shastry-Sutherland lattice are investigated using Monte Carlo simulations, in order to understand the fascinating spin ordering sequence observed in TmB4 and other rare-earth tetraborides. The simulation reproduces the experimental 1/2 magnetization plateau at low temperature by considering multifold long range interactions. It is found that more local long range interactions can be satisfied in the 1/2 plateau state than those in the 1/3 plateau state, leading to the stabilization of the extended 1/2 plateau. A mean-field theory on the spin ground states in response to magnetic field is proposed, demonstrating the simulation results. When the energies of the Neel state and the collinear state are degenerated, the former state is more likely to be stabilized due to the competitions among the local collinear spin orders. The present work provides a comprehensive proof of the phase transitions to the Neel state at nonzero temperature, in complimentary to the earlier predictions for the Fe-based superconductors., Comment: 19 Pages, 6 figures

Published
2012
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50. A physics-based predictive model for pulse design to realize high-performance memristive neural networks

Author

Deng, Haoyue, primary, Fan, Zhen, additional, Dong, Shuai, additional, Chen, Zhiwei, additional, Li, Wenjie, additional, Chen, Yihong, additional, Liu, Kun, additional, Tao, Ruiqiang, additional, Tian, Guo, additional, Chen, Deyang, additional, Qin, Minghui, additional, Zeng, Min, additional, Lu, Xubing, additional, Zhou, Guofu, additional, Gao, Xingsen, additional, and Liu, Jun-Ming, additional

Published
2023
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