Search

Your search keyword '"Kitaori, Aki"' showing total 9 results
Start Over Author "Kitaori, Aki"
9 results on '"Kitaori, Aki"'

1. Doping control of magnetism and emergent electromagnetic induction in high-temperature helimagnets

Author

Kitaori, Aki, White, Jonathan S., Kanazawa, Naoya, Ukleev, Victor, Singh, Deepak, Furukawa, Yuki, Arima, Taka-hisa, Nagaosa, Naoto, and Tokura, Yoshinori

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Ac current-driven motions of spiral spin textures can give rise to emergent electric fields acting on conduction electrons. This in turn leads to the emergent electromagnetic induction effect which may realize quantum inductor elements of micrometer size. ${\rm YMn}_{6}{\rm Sn}_{6}$ is a helimagnet with a short helical period (2-3 nm) that shows this type of emergent inductance beyond room temperature. To identify the optimized materials conditions for ${\rm YMn}_{6}{\rm Sn}_{6}$-type room-temperature emergent inductors, we have investigated emergent electromagnetic inductance (EEMI) as the magnetism is modified through systematic partial substitution of Y by Tb. By small angle neutron scattering and inductance measurements, we have revealed that the pinning effect on the spin-helix translational mode by Tb doping selectively and largely suppresses the negative component of EEMI, while sustaining the positive inductance arising from the spin tilting mode. We also find that in addition to the spin helix, even the spin-collinear antiferromagnetic structure can host the positive EEMI due to thermally enhanced spin fluctuations. The present study highlights the facile control of both the magnitude and sign of EEMI beyond room temperature, and thus suggests a route to expand the range of emergent inductor candidate materials., Comment: 20 pages, 13 figures

Published
2023
Full Text
View/download PDF

2. Enhanced Electrical Magnetochiral Effect by Spin-hedgehog Lattice Structural Transition

Author

Kitaori, Aki, Kanazawa, Naoya, Ishizuka, Hiroaki, Yokouchi, Tomoyuki, Nagaosa, Naoto, and Tokura, Yoshinori

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Nonreciprocal resistance, depending on both directions of current ($j$) and magnetic-field ($H$) or magnetization ($M$), is generally expected to emerge in a chiral conductor, and be maximized for $j$ $\parallel$ $H$($M$). This phenomenon, electrical magnetochiral effect (eMChE), is empirically known to increase with $H$ in a paramagnetic or fully ferromagnetic state on chiral lattice or to depend on fluctuation properties of a helimagnetic state. We report here the eMChE over a wide temperature range in the chiral-lattice magnet MnGe in which the spin hedgehog lattice (HL) forms with the triple spin-helix modulation vectors. The magnitude of nonreciprocal resistivity is sharply enhanced in the course of the field-induced structural transition of HL from cubic to rhombohedral form. This is attributed to the enhanced asymmetric electron scatterings by vector spin chirality in association with the large thermal fluctuations of spin hedgehogs., Comment: 8 pages, 7 figures

Published
2021
Full Text
View/download PDF

3. Emergent electromagnetic induction beyond room temperature

Author

Kitaori, Aki, Kanazawa, Naoya, Yokouchi, Tomoyuki, Kagawa, Fumitaka, Nagaosa, Naoto, and Tokura, Yoshinori

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Emergent electromagnetic induction based on electrodynamics of noncollinear spin states may enable dramatic miniaturization of inductor elements widely used in electric circuits, yet many issues are to be solved toward application. One such problem is how to increase working temperature. We report the large emergent electromagnetic induction achieved around and above room temperature based on short-period ($\leq$ 3 nm) spin-spiral states of a metallic helimagnet ${\rm YMn}_{6}{\rm Sn}_{6}$. The observed inductance value $L$ and its sign are observed to vary to a large extent, depending not only on the spin helix structure controlled by temperature and magnetic field but also on the current density. The present finding on room-temperature operation and possible sign control of $L$ may provide a new step toward realizing microscale quantum inductors., Comment: 19 pages, 6 figures

Published
2021
Full Text
View/download PDF

5. Enhanced emergent electromagnetic inductance in Tb5Sb3 due to highly disordered helimagnetism.

Author

Kitaori, Aki, White, Jonathan S., Ukleev, Victor, Peng, Licong, Nakajima, Kiyomi, Kanazawa, Naoya, Yu, Xiuzhen, Ōnuki, Yoshichika, and Tokura, Yoshinori

Subjects
*ELECTRIC inductance, *ELECTROMAGNETIC induction, *SMALL-angle neutron scattering, *SMALL-angle scattering, *ELECTRICAL resistivity, *CONDUCTION electrons, *ELECTRIC fields
Abstract

In helimagnetic metals, ac current-driven spin motions can generate emergent electric fields acting on conduction electrons, leading to emergent electromagnetic induction (EEMI). Recent experiments reveal the EEMI signal generally shows a strongly current-nonlinear response. In this study, we investigate the EEMI of Tb5Sb3, a short-period helimagnet. Using small angle neutron scattering we show that Tb5Sb3 hosts highly disordered helimagnetism with a distribution of spin-helix periodicity. The current-nonlinear dynamics of the disordered spin helix in Tb5Sb3 indeed shows up as the nonlinear electrical resistivity (real part of ac resistivity), and even more clearly as a nonlinear and huge EEMI (imaginary part of ac resistivity) response. The magnitude of the EEMI reaches as large as several tens of μH for Tb5Sb3 devices on the scale of several tens of μm, originating to noncollinear spin textures possibly even without long-range helimagnetic order. Ac current-driven spin motions in helimagnetic metals can generate emergent electric fields acting on conduction electrons, leading to emergent electromagnetic induction (EEMI). In this study, we revealed that a short-period helimagnet Tb5Sb3 may have disordered spin helix structure and provides large EEMI. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

6. Magnetic Properties of Single Crystalline Tb5Sb3

Author

Kitaori, Aki, primary, Kanazawa, Naoya, additional, Kida, Takanori, additional, Narumi, Yasuo, additional, Hagiwara, Masayuki, additional, Kindo, Koichi, additional, Takeuchi, Tetsuya, additional, Nakamura, Ai, additional, Aoki, Dai, additional, Haga, Yoshinori, additional, Kaneko, Yoshio, additional, Tokura, Yoshinori, additional, and Ōnuki, Yoshichika, additional

Published
2023
Full Text
View/download PDF

8. Magnetic Properties of Single Crystalline Tb5Sb3.

Author

Kitaori, Aki, Kanazawa, Naoya, Kida, Takanori, Narumi, Yasuo, Hagiwara, Masayuki, Kindo, Koichi, Takeuchi, Tetsuya, Nakamura, Ai, Aoki, Dai, Haga, Yoshinori, Kaneko, Yoshio, Tokura, Yoshinori, and Ōnuki, Yoshichika

Abstract

We have successfully grown single crystalline Tb5Sb3 with the hexagonal structure, which was reported to exhibit successive transitions among complex spiral magnetic structures with changing temperature. Through the measurements of specific heat and magnetization of the single crystalline Tb5Sb3, we have identified only one clear magnetic transition at 133 K. The ordered moments are approximately oriented in the hexagonal basal plane, while the hard axis of magnetization corresponds to the [0001] direction. This magnetic structure with the ferromagnetic-like order is transformed below 50 K, resulting in a rapid decrease in the magnetic susceptibility for \(H\parallel [10\bar{1}0]\) and a kink behavior in a low-field magnetization, although the nearly ferromagnetic state continues below 50 K, revealing a hysteresis in the magnetization curve. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results