Your search keyword '"Antiferromagnetic skyrmion"' showing total 8 results

1. Elongated antiferromagnetic skyrmion in two-dimensional RuF4

Author

Lan, Mu, Wang, Rong, Wei, Shihao, Li, Lezhong, Ren, Wenning, Zhang, Xing, Zhang, Xi, and Xiang, Gang

Published

2024

2. Suppression of Skyrmion Hall Motion in Antiferromagnets Driven by Circularly Polarized Spin Waves

Author

S. H. Guan, Y. Yang, Z. Jin, T. T. Liu, Y. Liu, and M. H. Qin

Subjects

antiferromagnetic skyrmion, spin waves, dynamics, Hall motion, speed, Physics, QC1-999

Abstract

An investigation of spin waves interacting with antiferromagnetic spin textures is meaningful for future spintronic and magnonic-based memory and logic applications. In this work, we numerically study the skyrmion dynamics driven by circularly polarized spin waves in antiferromagnets and propose a method of suppressing the Hall motion. It is demonstrated that the application of two circularly polarized spin waves with opposite chirality allows the skyrmion motion straightly along the intersection line of the two spin wave sources. The skyrmion speed depending on these parameters of the spin waves and system is estimated, and a comparison with other methods is provided. Furthermore, two depinning behaviors of the skyrmion related to the strengths of the defect are also observed in the simulations. Thus, the proposed method could be used in precisely modulating the skyrmion dynamics, contributing to skyrmion-based memory device design.

Published

2021

3. 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

*SKYRMIONS, *MOTION

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's theory. This work unveils a promising strategy to enhance the stability and the maximum velocity of AFM skyrmion, benefiting future spintronic applications. [ABSTRACT FROM AUTHOR]

Published

2020

4. Reconfigurable Skyrmion-Based Logic Gates: Versatile Design and Full-Scale Implementation.

Author

Belrhazi H, Fattouhi M, El Hafidi MY, and El Hafidi M

Abstract

Herein, we investigate the behavior of skyrmions within a racetrack design incorporating voltage-controlled magnetic anisotropy (VCMA) gates. Our analysis encompassed multiple forces, including spin currents and anisotropy gradients induced by bias voltages. As a result, the efficient control of skyrmion dynamics was achieved across various VCMA gate configurations. Building upon these findings, we propose an efficient approach to reconfigurable skyrmion logic (RSL) in a thin antiferromagnetic (AFM) film through a versatile design. Our RSL harnesses the selective integration of VCMA, spin-polarized currents, and skyrmion-skyrmion (sky-sky) interactions to implement multiple logic gates, including AND, OR, XOR, NOT, NAND, XNOR, and NOR. The design brings a significant advantage with its simplified fabrication process, making the implementation of the RSL practical and accessible for various applications. Furthermore, the RSL enables seamless dynamic switching between logic gates, thereby enhancing its multifunctionality. Additionally, the strategic incorporation of sky-sky interactions and skyrmion-edge repulsion prominently facilitates the realization of complex gates, such as NAND, XNOR, and NOR gates, that typically require intricate design efforts. Hence, this streamlined integration of RSL, coupled with its adaptability to changing computational needs, underscores its potential as a practical solution for implementing high-functionality skyrmion-based logic gates.

Published

2024

5. Stability of atomic-sized skyrmions in antiferromagnetic bilayers.

Author

Jaeschke-Ubiergo, Rodrigo and Nunez, Alvaro S.

Subjects

*SKYRMIONS, *GROUND state energy, *ATOMIC radius, *ACTIVATION energy, *MAGNETIC fields

Abstract

We perform a stability analysis of an isolated atomic-sized antiferromagnetic skyrmion (AFM-Sk), formed on the superior layer of a magnetic bilayer. The coupling between both square lattices acts as an effective staggered magnetic field that stabilizes the AFM-Sk and reduces its radius. A suitable anisotropy constant of the bottom layer material keeps it close to the homogeneous AFM state. We compare the energy of the AFM-Sk with the energy of the AFM ground state. In addition, an estimation of the energy barrier that protects the skyrmion from being destabilized is provided and its value determined to be in the order of ∼ 300 K. The remarkable reduction in the skyrmion radius towards atomic size and avoiding an external magnetic field are key points in order to increase our ability to manipulate AFM-Sk on skyrmionic devices. Our calculations provide an insight into novel ways to create and manipulate AFM-Sk at the atomic scale. [ABSTRACT FROM AUTHOR]

Published

2019

6. Estudo via simulação computacional da estabilidade de Skyrmions em filmes antiferromagnéticos e suas interações com impurezas magnéticas

Author

Guedes, Robson César de Oliveira, Leonel, Sidiney de Andrade, Pereira, Afrânio Rodrigues, and Coura, Pablo Zimmermann

Subjects

Nanomagnetismo, Antiferromagnetic skyrmion, Nanomagnetism, Simulação micromagnética, Spintrônica, Landau-Lifshitz-Gilbert Equation, Equação de Landau-Lifshitz-Gilbert, Micromagnetic simulation, Skyrmion antiferromagnético, CIENCIAS EXATAS E DA TERRA::FISICA [CNPQ]

Abstract

Skyrmions são quase-partículas que contam com características que os tornam viáveis para a aplicação em novas gerações de dispositivos de memórias e de processamento de dados. Isso é devido ao seu pequeno tamanho, sua estabilidade e à sua alta mobilidade em sistemas magnéticos quase bidimensionais. Skyrmions antiferromagnéticos se sobressaem aos skyrmions ferromagnéticos por necessitarem de densidade de corrente menor e não apresentarem Efeito Hall de Skyrmion em sua dinâmica. É necessário entender como um skyrmion antiferromagnético se comporta em uma nanotrilha, o controle de sua posição e de seu tamanho é de fundamental importância para sua aplicação em dispositivos spintrônicos. No presente trabalho estudamos o comportamento de um skyrmion antiferromagnético estabilizado em uma bicamada formada por trifluoreto de potássio manganês sobre platina (KMnF3/P t). Nossos estudos foram feitos via simulação computacional micromagnética utilizando um software próprio desenvolvido pelo nosso grupo de pesquisa. Como resultado verificamos que o balanço das interações de Dzyaloshinskii-Moriya e anisotropia magnetocristalina perpendicular é de fundamental importância na estabilização de skyrmions antiferromagnéticos, bem como no seu tamanho e forma. Obtendo o estado de equilíbrio de um skyrmion inicialmente posicionado em uma interface entre dois meios antiferromagnéticos distintos, verificamos que a quase-partícula é atraída ou repelida para uma região magneticamente modificada, com isso concluímos que é possível a construção de armadinhas para skyrmions antiferromagnéticos. As armadilhas para skyrmions são importantes no controle de sua posição na nanotrilha, visto que a existência ou ausência do skyrmion em determinada região pode armazenar informação de forma binária. Acreditamos que este estudo seja útil como guia na busca de novos materiais capazes de estabilizar skyrmions antiferromagnéticos. Os resultados contidos neste trabalho corroboram ou ampliam os estudos em skyrmions antiferromagnéticos. Skyrmions are quasi-particles that have characteristics that make them viable for application in new generation memory and data processing devices. This is due to its small size, its stability, and its high mobility in nearly two-dimensional magnetic systems. Antiferromagnetic skyrmions stand out from ferromagnetic skyrmions because they need a lower current density and do not show Skyrmion Hall Effect in their dynamics. It is necessary to understand how an antiferromagnetic skyrmion behaves in a nanotrack, the control of its position and size is of fundamental importance for its application in spintronic devices. In this work we study the behavior of an antiferromagnetic skyrmion stabilized in a bilayer formed by potassium manganese trifluoride on platinum (KMnF3/P t). Our studies were carried out via micromagnetic computer simulation using proprietary software developed by our research group. As a result, we verified that the balance of Dzyaloshinskii-Moriya interactions and perpendicular magneto crystalline anisotropy is of fundamental importance in the stabilization of antiferromagnetic skyrmions, as well as in their size and shape. Obtaining the equilibrium state of a skyrmion initially positioned at the interface between two distinct antiferromagnetic means, we verified that the quasi-particle is attracted or repelled to a magnetically modified region, with this we conclude that it is possible to build traps for antiferromagnetic skyrmions. Skyrmion traps are important in controlling their position on the nano trail since the existence or absence of the skyrmion in a certain region can store information in binary form. We believe that this study is useful as a guide in the search for new materials capable of stabilizing antiferromagnetic skyrmions. The results contained in this work corroborate or extend the studies on antiferromagnetic skyrmions.

Published

2021

7. Suppression of Skyrmion Hall Motion in Antiferromagnets Driven by Circularly Polarized Spin Waves

Author

Minghui Qin, Yang Yang, Z. Jin, T. T. Liu, Yong Liu, and S. H. Guan

Subjects

Physics, Hall motion, Spintronics, Condensed matter physics, Materials Science (miscellaneous), Skyrmion, QC1-999, Dynamics (mechanics), Biophysics, General Physics and Astronomy, speed, dynamics, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Chirality (electromagnetism), spin waves, antiferromagnetic skyrmion, Intersection, Spin wave, Antiferromagnetism, Condensed Matter::Strongly Correlated Electrons, Physical and Theoretical Chemistry, Mathematical Physics, Spin-½

Abstract

An investigation of spin waves interacting with antiferromagnetic spin textures is meaningful for future spintronic and magnonic-based memory and logic applications. In this work, we numerically study the skyrmion dynamics driven by circularly polarized spin waves in antiferromagnets and propose a method of suppressing the Hall motion. It is demonstrated that the application of two circularly polarized spin waves with opposite chirality allows the skyrmion motion straightly along the intersection line of the two spin wave sources. The skyrmion speed depending on these parameters of the spin waves and system is estimated, and a comparison with other methods is provided. Furthermore, two depinning behaviors of the skyrmion related to the strengths of the defect are also observed in the simulations. Thus, the proposed method could be used in precisely modulating the skyrmion dynamics, contributing to skyrmion-based memory device design.

Published

2021

8. Unidirectional localization and track-selection of antiferromagnetic skyrmions through tuning magnetocrystalline anisotropy barriers.

Author

Guan, S.H., Yang, Y., Jin, Z., Liu, T.T., Liu, Y., Hou, Z.P., Chen, D.Y., Fan, Z., Zeng, M., Lu, X.B., Gao, X.S., Qin, M.H., and Liu, J.-M.

Subjects

*SKYRMIONS, *MAGNETIC anisotropy, *CRYSTAL defects, *ANTIFERROMAGNETIC materials

Abstract

• We theoretically proposed a method to localize the antiferromagnetic skyrmions. • The stable pinning of the skyrmion for certain ranges of injected current is demonstrated. • A precise track-selecting of the antiferromagnetic skyrmions is proposed. Reliable detection of antiferromagnetic (AFM) structures remains an open issue in experiments, although these structures such as skyrmions are suggested to play an important role in future spintronic applications. In this work, we theoretically proposed an alternative method to localize the AFM skyrmions along the direction of driving force through tuning magnetic anisotropy barriers by linear lattice defect design. The dependence of the depinning current on the magnitude and width of the defects and temperature is numerically investigated by solving the Landau-Lifshitz-Gilbert equation and also derived based on the Thiele's theory. The stable pinning of the skyrmion for certain ranges of the injected current is clearly demonstrated, which suggests an effective way in localizing the skyrmion. Based on the calculated results, we propose a method of precise track-selecting of the AFM skyrmions, which are meaningful for future two- and three- dimensional AFM spintronic device design. [ABSTRACT FROM AUTHOR]

Published

2022