Logic Operations Based on Magnetic-Vortex-State Networks

Jung, Hyun-Kyo; Choi, Youn-Seok; Lee, Ki-Suk; Han, Dong‐Soo; Yu, Young‐Sang; Im, Mi‐Young; Fischer, Peter; Kim, Sang‐Koog

doi:10.1021/nn3000143

Cited by 91 publications

(74 citation statements)

References 28 publications

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“…magnetic wires bearing spin waves [3][4][5][6][7] or domain walls, [8][9][10] or nanomagnet networks. [11][12][13][14][15][16] The devices using spin waves represent a prospective direction taking into account their intrinsic low-power character, two usable features for processing, i.e. the amplitude and phase 3 (the latter is frequency-and wavenumber-dependent) of spin waves, and many available intrinsic attributes specific to waves [17][18][19][20] such as interference.…”

Section: Introductionmentioning

confidence: 99%

Engineering spin-wave channels in submicrometer magnonic waveguides

Xing

Wang

2013

AIP Advances

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Based on micromagnetic simulations and model calculations, we demonstrate that degenerate well and barrier magnon modes can exist concurrently in a single magnetic waveguide magnetized perpendicularly to the long axis in a broad frequency band, corresponding to copropagating edge and centre spin waves, respectively. The dispersion relations of these magnon modes clearly show that the edge and centre modes possess much different wave characteristics. By tailoring the antenna size, the edge mode can be selectively activated. If the antenna is sufficiently narrow, both the edge and centre modes are excited with considerable efficiency and propagate along the waveguide. By roughening the lateral boundary of the waveguide, the characteristics of the relevant channel can be easily engineered. Moreover, the coupling of the edge and centre modes can be conveniently controlled by scaling the width of the waveguide. For a wide waveguide with a narrow antenna, the edge and centre modes travel relatively independently in spatially-separate channels, whereas for a narrow strip, these modes strongly superpose in space. These discoveries might find potential applications in emerging magnonic devices

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Section: Introductionmentioning

confidence: 99%

Engineering spin-wave channels in submicrometer magnonic waveguides

Xing

Wang

2013

AIP Advances

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“…1,2 Because both circularity and polarity can be specified by two independent values, that is, c = ± 1 and p = ± 1, four distinct spin states can exist in a single magnetic element with the combination of circularity and polarity. Magnetic vortices have been intensively studied due to their compelling physical behavior [3][4][5][6][7] and their potential in a wide range of applications such as data storage, 8,9 signal transfer, [10][11][12] logic devices, 13 transistors 14 and artificial skyrmion crystals. [15][16][17][18] With respect to practical application of magnetic vortices in advanced nanotechnologies, one of the critical factors is the effective reconfigurability of two topologies, c and p, particularly within large and densely packed arrays of magnetic elements.…”

Section: Introductionmentioning

confidence: 99%

“…19,20 As a representative example, for successful achievement of vortex-based signal transfer and logic and transistor operations, the desired configurations of magnetic vortex states must be first established. [10][11][12][13][14] Additionally, uniformly arranged vortex structures are also required to generate artificial skyrmion crystals based on magnetic vortices in proximity to perpendicularly magnetized thin films. [15][16][17][18] For effective reconfiguration of magnetic vortex structures, one key issue is reliable and efficient control of both c and p in magnetic vortices, which is also vital for storage applications.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous control of magnetic topologies for reconfigurable vortex arrays

Fischer

Han

et al. 2017

NPG Asia Mater

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The topological spin textures in magnetic vortices in confined magnetic elements offer a platform for understanding the fundamental physics of nanoscale spin behavior and the potential of harnessing their unique spin structures for advanced magnetic technologies. For magnetic vortices to be practical, an effective reconfigurability of the two topologies of magnetic vortices, that is, the circularity and the polarity, is an essential prerequisite. The reconfiguration issue is highly relevant to the question of whether both circularity and polarity are reliably and efficiently controllable. In this work, we report the first direct observation of simultaneous control of both circularity and polarity by the sole application of an in-plane magnetic field to arrays of asymmetrically shaped permalloy disks. Our investigation demonstrates that a high degree of reliability for control of both topologies can be achieved by tailoring the geometry of the disk arrays. We also propose a new approach to control the vortex structures by manipulating the effect of the stray field on the dynamics of vortex creation. The current study is expected to facilitate complete and effective reconfiguration of magnetic vortex structures, thereby enhancing the prospects for technological applications of magnetic vortices.

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“…Many of these proposed spintronic devices utilize magnetic solitons constrained as fundamental elements in mesoscopic and nanoscopic ferromagnetic (FM) structures. The remarkable stability of topological solitons and other highly localized nanomagnetic structures under spin currents and Oersted field excitation has not only motivated spin-based oscillator technologies, but also memories and logic devices [1][2][3][4][5][6][7][8][9][10][11][12] . Notably, magnetic vortices are a type of quasi-particle that possess an out-of-plane magnetization, known as the vortex core polarity P ¼ [ þ , À ] (up or down), and an inplane circular magnetization surrounding the core C ¼ [ þ , À ] (clockwise or anti-clockwise), often referred to as the chirality 13 .…”

mentioning

confidence: 99%

Coherence and modality of driven interlayer-coupled magnetic vortices

et al. 2014

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The high-frequency dynamics of mode-coupled magnetic vortices have generated great interest for spintronic technologies, such as spin-torque nano-oscillators. While the spectroscopic characteristics of vortex oscillators have been reported, direct imaging of driven coupled magnetic quasi-particles is essential to the fundamental understanding of the dynamics involved. Here, we present the first direct imaging study of driven interlayer coaxial vortices in the dipolar-and indirect exchange-coupled regimes. Employing in situ highfrequency excitation with Lorentz microscopy, we directly observe the steady-state orbital amplitudes in real space with sub-5 nm spatial resolution. We discuss the unique frequency response of dipolar-and exchange-coupled vortex motion, wherein mode splitting and locking demonstrates large variations in coherent motion, as well as detail the resultant orbital amplitudes. This provides critical insights of the fundamental features of collective vortex-based microwave generators, such as their steady-state amplitudes, tunability and mode-coupled motion.

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Logic Operations Based on Magnetic-Vortex-State Networks

Cited by 91 publications

References 28 publications

Engineering spin-wave channels in submicrometer magnonic waveguides

Engineering spin-wave channels in submicrometer magnonic waveguides

Simultaneous control of magnetic topologies for reconfigurable vortex arrays

Coherence and modality of driven interlayer-coupled magnetic vortices

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