Your search keyword '"Im, Mi‐Young"' showing total 3 results

1. Manipulation of the magnetic monopole injection for topological transition

Author

Han, Hee-Sung, Montoya, Sergio A, Fullerton, Eric E, Chao, Weilun, Je, Soong-Geun, Lee, Ki‐Suk, and Im, Mi-Young

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Engineering, Materials Engineering, Condensed Matter Physics, Physical Chemistry (incl. Structural), Macromolecular and materials chemistry, Physical chemistry, Materials engineering

Abstract

Manipulating the topological properties of spin textures in magnetic materials is of great interest due to the rich physics and promising technological applications of these materials in advanced electronic devices. A spin texture with desired topological properties can be created by magnetic monopole injection, resulting in topological transitions involving changes in the topological charge. Therefore, controlling magnetic monopole injection has paramount importance for obtaining the desired spin textures but has not yet been reported. Here, we report the use of reliably manipulated magnetic monopole injection in the topological transition from stripe domains to skyrmions in an Fe/Gd multilayer. An easily tunable in-plane magnetic field applied to an Fe/Gd multilayer plays a key role in the magnetic monopole injection by modulating the local exchange energy. Our findings facilitate the efficient management of topological transitions by providing an important method for controlling magnetic monopole injection.

Published

2024

2. Tuning of oscillation modes by controlling dimensionality of spin structures

Author

Han, Hee-Sung, Lee, Sooseok, Jung, Min-Seung, Kim, Namkyu, Jung, Dae-Han, Kang, Myeonghwan, Ok, Hye-Jin, Chao, Weilun, Yu, Young-Sang, Hong, Jung-Il, Im, Mi-Young, and Lee, Ki‐Suk

Subjects

Engineering, Nanotechnology, Condensed Matter Physics, Physical Chemistry (incl. Structural), Materials Engineering, Macromolecular and materials chemistry, Physical chemistry, Materials engineering

Abstract

Harmonic oscillation of spin structures is a physical phenomenon that offers great potential for applications in nanotechnologies such as nano-oscillators and bio-inspired computing. The effective tuning of oscillations over wide frequency ranges within a single ferromagnetic nanoelement is a prerequisite to realize oscillation-based nanodevices, but it has not been addressed experimentally or theoretically. Here, utilizing a vortex core structure, one of spin structures, we report a drastic change of oscillation modes over the frequency range from MHz to sub-GHz in a 100 nm-thick permalloy circular disk. Oscillation mode was found to considerably depend on the shape and dimension of the vortex core structure and various oscillation modes over a wide range of frequencies appeared with dimensional change in the vortex core structure. This work demonstrates that oscillation modes of the vortex core structure can be effectively tuned and opens a way to apply spin structures to oscillation-based technology.

Published

2022

3. Simultaneous control of magnetic topologies for reconfigurable vortex arrays

Author

Im, Mi-Young, Fischer, Peter, Han, Hee-Sung, Vogel, Andreas, Jung, Min-Seung, Chao, Weilun, Yu, Young-Sang, Meier, Guido, Hong, Jung-Il, and Lee, Ki-Suk

Subjects

Engineering, Materials Engineering, Condensed Matter Physics, Physical Chemistry (incl. Structural), Macromolecular and materials chemistry, Physical chemistry, Materials engineering

Abstract

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.

Published

2017