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1. Circular photogalvanic effect in an inversion-symmetry-broken bilayer germanium nanosheet

Author

Nishijima, Taiki, Shigematsu, Ei, Ohshima, Ryo, Matsushita, Keigo, Ohta, Akio, Araidai, Masaaki, Yuhara, Junji, Kurosawa, Masashi, Shiraishi, Masashi, and Ando, Yuichiro

Subjects
Condensed Matter - Materials Science
Abstract

Spin-to-charge conversion in monolayer and bilayer germanium(Ge) nanosheets was demonstrated via the circular photogalvanic effect (CPGE). The CPGE current generated in a spin-splitting state of the Ge nanosheet reached a maximum value when the thickness of the Ge nanosheet corresponded to bilayer germanene, indicating that the top layer of the bilayer Ge nanosheet mainly contributed to the spin-to-charge conversion. Because the hybridization of orbitals is suppressed by isolation from the bottom Al layer for the top Ge nanosheet, the observed spin-to-charge conversion has a possibility to be related to the intrinsic features of germanene with breaking of inversion symmetry., Comment: 18pages, 4figures

Published
2024

2. Emergence of giant spin-orbit torque in a two-dimensional hole gas on the hydrogen-terminated diamond surface

Author

Sako, Fujio, Ohshima, Ryo, Ando, Yuichiro, Morioka, Naoya, Kawashima, Hiroyuki, Kawase, Riku, Mizuochi, Norikazu, Huebl, Hans, and Shiraishi, Masashi

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Two-dimensional (2D) carrier systems exhibit various significant physical phenomena for electronics and spintronics, where one of the most promising traits is efficient spin-to-charge conversion stemming from their Rashba-type spin-orbit interaction. Meanwhile, a nuisance in quests of promising materials for spintronics application is that vast majority of the investigated platforms consists of rare and/or toxic elements, such as Pt and Te, which hinders progress of spin conversion physics in view of element strategy and green technology. Here, we show the emergence of giant spin-orbit torque driven by 2D hole gas at the surface of hydrogen-terminated diamond, where the constituent substances are ubiquitous elements, carbon and hydrogen. The index of its spin torque efficiency at room temperature is several times greater than that of rare metal, Pt, the benchmark system/element for spin-to-charge conversion. Our finding opens a new pathway for more sustainable spintronics and spin-orbitronics applications, with efficient spin-orbit torque employing ubiquitous non-toxic elements., Comment: 19pages, 4figures

Published
2024

3. Field-free superconducting diode effect in layered superconductor FeSe

Author

Nagata, Utane, Aoki, Motomi, Daido, Akito, Kasahara, Shigeru, Kasahara, Yuichi, Ohshima, Ryo, Ando, Yuichiro, Yanase, Youichi, Matsuda, Yuji, and Shiraishi, Masashi

Subjects
Condensed Matter - Materials Science, Condensed Matter - Superconductivity
Abstract

The superconducting diode effect (SDE), where zero-resistance states appear nonreciprocally during current injection, is receiving tremendous interest in both fundamental and applied physics because the SDE is a novel manifestation of symmetry breaking and enables the creation of a novel diode without energy loss. In particular, magnetic-field-free SDEs have been extensively investigated because of their potential to serve as building blocks for superconducting circuit technology. In this letter, we report the field-free SDE in a layered superconductor, FeSe. Its underlying physics is clarified by systematic controlled experiments to be an interplay of a large thermoelectric response and geometrical asymmetry in FeSe. Our findings can pave a new avenue for the construction of novel material and device platforms utilizing SDEs., Comment: 16 pages, 5 figures

Published
2024

4. Gigantic Anisotropy of Self-Induced Spin-Orbit Torque in Weyl Ferromagnet Co2MnGa

Author

Aoki, Motomi, Yin, Yuefeng, Granville, Simon, Zhang, Yao, Medhekar, Nikhil V., Leiva, Livio, Ohshima, Ryo, Ando, Yuichiro, and Shiraishi, Masashi

Subjects
Condensed Matter - Materials Science
Abstract

Spin-orbit torque (SOT) is receiving tremendous attention from both fundamental and application-oriented aspects. Co2MnGa, a Weyl ferromagnet that is in a class of topological quantum materials, possesses cubic-based high structural symmetry, the L21 crystal ordering, which should be incapable of hosting anisotropic SOT in conventional understanding. Here we show the discovery of a gigantic anisotropy of self-induced SOT in Co2MnGa. The magnitude of the SOT is comparable to that of heavy metal/ferromagnet bilayer systems despite the high inversion symmetry of the Co2MnGa structure. More surprisingly, a sign inversion of the self-induced SOT is observed for different crystal axes. This finding stems from the interplay of the topological nature of the electronic states and their strong modulation by external strain. Our research enriches the understanding of the physics of self-induced SOT and demonstrates a versatile method for tuning SOT efficiencies in a wide range of materials for topological and spintronic devices., Comment: 15pages, 4figures (To appear Nano Lett.)

Published
2023
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5. Modulation of Hanle magnetoresistance in an ultrathin platinum film by ionic gating

Author

Maruyama, Yuu, Ohshima, Ryo, Shigematsu, Ei, Ando, Yuichiro, and Shiraishi, Masashi

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Hanle magnetoresistance (HMR) is a type of magnetoresistance where interplay of the spin Hall effect, Hanle-type spin precession, and spin-dependent scattering at the top/bottom surfaces in a heavy metal controls the effect. In this study, we modulate HMR in ultrathin Pt by ionic gating, where the surface Rashba field created by a strong electric field at the interface between the ionic gate and Pt plays the dominant role in the modulation. This finding can facilitate investigations of gate-tunable, spin-related effects and fabrication of spin devices., Comment: 10 pages, 3 figures (To appear in Applied Physics Express)

Published
2023
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6. Anomalous sign inversion of spin-orbit torque in ferromagnetic/nonmagnetic bilayer systems due to self-induced spin-orbit torque

Author

Aoki, Motomi, Shigematsu, Ei, Ohshima, Ryo, Shinjo, Teruya, Shiraishi, Masashi, and Ando, Yuichiro

Subjects
Condensed Matter - Materials Science
Abstract

Self-induced spin-orbit torques (SI-SOTs) in ferromagnetic (FM) layers have been overlooked when estimating the spin Hall angle (SHA) of adjacent nonmagnetic (NM) layers. In this work, we observe anomalous sign inversion of the total SOT in the spin-torque ferromagnetic resonance due to the enhanced SI-SOT, and successfully rationalize the sign inversion through a theoretical calculation considering the SHE in both the NM and FM layers. The findings show that using an FM layer whose SHA sign is the same as that of the NM achieves efficient SOT-magnetization switching with the assistance of the SI-SOT. The contribution of the SI-SOT becomes salient for a weakly conductive NM layer, and conventional analyses that do not consider the SI-SOT can overestimate the SHA of the NM layer by a factor of more than 150., Comment: 9 pages, 4 figures

Published
2022
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7. All-electric spin device operation using the Weyl semimetal, WTe$_2$, at room temperature

Author

Ohnishi, Kosuke, Aoki, Motomi, Ohshima, Ryo, Shigematsu, Ei, Ando, Yuichiro, Takenobu, Taishi, and Shiraishi, Masashi

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Topological quantum materials (TQMs) possess abundant and attractive spin physics, and a Weyl semimetal is the representative material because of the generation of spin polarization that is available for spin devices due to fictitious Weyl monopoles at the edge of the Weyl node. Meanwhile, a Weyl semimetal allows the other but unexplored spin polarization due to local symmetry breaking. Here, we report all-electric spin device operation using a type-II Weyl semimetal, WTe$_2$, at room temperature. The polarization of spins propagating in the all-electric device is perpendicular to the WTe$_2$ plane, which is ascribed to local in-plane symmetry breaking in WTe$_2$, yielding the spin polarization creation of propagating charged carriers, namely, the spin-polarized state creation from the non-polarized state. Systematic control experiments unequivocally negate unexpected artifacts, such as the anomalous Hall effect, the anisotropic magnetoresistance etc. Creation of all-electric spin devices made of TQMs and their operation at room temperature can pave a new pathway for novel spin devices made of TQMs resilient to thermal fluctuation., Comment: 20 pages, 4 figures

Published
2022
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8. Observation of gigantic spin conversion anisotropy in bismuth

Author

Fukumoto, Naoki, Ohshima, Ryo, Aoki, Motomi, Fuseya, Yuki, Matsushima, Masayuki, Shigematsu, Ei, Shinjo, Teruya, Ando, Yuichiro, Sakamoto, Shoya, Shiga, Masanobu, Miwa, Shinji, and Shiraishi, Masashi

Subjects
Condensed Matter - Materials Science
Abstract

Whilst the g-factor can be anisotropic due to the spin-orbit interaction (SOI), its existence in solids cannot be simply asserted from a band structure, which hinders progress on studies from such the viewpoints. The g-factor in bismuth (Bi) is largely anisotropic; especially for holes at T-point, the g-factor perpendicular to the trigonal axis is negligibly small (< 0.112), whereas the g-factor along the trigonal axis is very large (62.7). We clarified in this work that the large g- factor anisotropy gives rise to the gigantic spin conversion anisotropy in Bi from experimental and theoretical approaches. Spin-torque ferromagnetic resonance was applied to estimate the spin conversion efficiency in rhombohedral (110) Bi to be 17%, which is unlike the negligibly small efficiency in Bi(111). Harmonic Hall measurements supports the large spin conversion efficiency in Bi(110). This is the first observation of gigantic spin conversion anisotropy as the clear manifestation of the g-factor anisotropy. Beyond the emblematic case of Bi, our study unveiled the significance of the g-factor anisotropy in condensed-matter physics and can pave a pathway toward establishing novel spin physics under g-factor control., Comment: 28 pages, 7 figures

Published
2022
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9. Inplane spin orbit torque magnetization switching and its detection using the spin rectification effect at sub-GHz frequencies

Author

Aoki, Motomi, Shigematsu, Ei, Ohshima, Ryo, Honda, Syuta, Shinjo, Teruya, Shiraishi, Masashi, and Ando, Yuichiro

Subjects
Condensed Matter - Materials Science
Abstract

Inplane magnetization reversal of a permalloy/platinum bilayer was detected using the spin rectification effect. Using a sub GHz microwave frequency to excite spin torque ferromagnetic resonance (ST FMR) in the bilayer induces two discrete DC voltages around an external static magnetic field of 0 mT. These discrete voltages depend on the magnetization directions of the permalloy and enable detection of the inplane magnetization reversal. The threshold current density for the magnetization reversal is from 10 to 20 MA/cm^2, the same order as for known spin orbit torque (SOT) switching with in-plane magnetization materials. The magnitude of the signal is the same or larger than that of the typical ST FMR signal; that is, detection of magnetization switching is highly sensitive in spite of deviation from the optimal ST-FMR condition. The proposed method is applicable to a simple device structure even for a small ferromagnetic electrode with a width of 100 nm.

Published
2020
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10. Modulation of spin conversion in a 1.5 nm-thick Pd film by ionic gating

Author

Yoshitake, Shin-ichiro, Ohshima, Ryo, Shinjo, Teruya, Ando, Yuichiro, and Shiraishi, Masashi

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

Gate-induced modulation of the spin-orbit interaction (SOI) in a 1.5 nm-thick Pd thin film grown on a ferrimagnetic insulator was investigated. Efficient charge accumulation by ionic gating enables a substantial upshift in the Fermi level of the Pd film, which was corroborated by suppression of the resistivity in the Pd. Electromotive forces arising from the inverse spin Hall effect in Pd under spin pumping were substantially modulated by the gating, in consequence of the modulation of the spin Hall conductivity of Pd as in an ultrathin Pt film. The same experiment using a thin Cu film, for which the band structure is largely different from Pd and Pt and its SOI is quite small, provides further results supporting our claim. The results obtained help in developing a holistic understanding of the gate-tunable SOI in solids and confirm a previous explanation of the significant modulation of the spin Hall conductivity in an ultrathin Pt film by gating., Comment: 15 pages, 4 figures

Published
2020

11. Spin transport in a lateral spin valve with a suspended Cu channel

Author

Matsuki, Kenjiro, Ohshima, Ryo, Leiva, Livio, Ando, Yuichiro, Shinjo, Teruya, Tsuchiya, Toshiyuki, and Shiraishi, Masashi

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

We study spin transport through a suspended Cu channel by an electrical non-local 4-terminal measurement for future spin mechanics applications. A magnetoresistance due to spin transport through the suspended Cu channel is observed, and its magnitude is comparable to that of a conventional fixed Cu lateral spin valve. The spin diffusion length in the suspended Cu channel is estimated to be 340 nm at room temperature from the spin signal dependence on the distance between the ferromagnetic injector and detector electrodes. This value is found to be slightly shorter than in a fixed Cu. The decrease in the spin diffusion length in the suspended Cu channel is attributed to an increase in spin scattering originating from naturally oxidized Cu at the bottom of the Cu channel., Comment: 12 pages, 3 figures (To appear in Scientific Reports)

Published
2020

12. Optical visualization of the enhanced spin Hall effect in bismuth doped silicon

Author

Nishijima, Taiki, Liu, Yakun, Kumar, Dushyant, Lee, Kyusup, Rortais, Fabien, Honda, Syuta, Ando, Yuichiro, Shigematsu, Ei, Ohshima, Ryo, Yang, Hyunsoo, and Shiraishi, Masashi

Subjects
Condensed Matter - Materials Science
Abstract

Direct visualizations of spin accumulation due to the enhanced spin Hall effect (SHE) in bismuth (Bi) - doped silicon (Si) at room temperature are realized by using helicity-dependent photovoltage (HDP) measurements. Under application of a dc current to the Bi-doped Si, clear helicity-dependent photovoltages are detected at the edges of the Si channel, indicating a perpendicular spin accumulation due to the SHE. In contrast, the HDP signals are negligibly small for phosphorus-doped Si. Compared to a platinum channel, which has a large spin Hall angle, more than two-orders of magnitude larger HDP signals are obtained in the Bi-doped Si.

Published
2020

13. Investigation of gating effect in Si spin MOSFET

Author

Lee, Soobeom, Rortais, Fabien, Ohshima, Ryo, Ando, Yuichiro, Goto, Minori, Miwa, Shinji, Suzuki, Yoshishige, Koike, Hayato, and Shiraishi, Masashi

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

A gate voltage application in a Si-based spin metal-oxide-semiconductor field-effect transistor (spin MOSFET) modulates spin accumulation voltages, where both electrical conductivity and drift velocity are modified while keeping constant electric current. An unprecedented reduction in the spin accumulation voltages in a Si spin MOSFET under negative gate voltage applications is observed in a high electric bias current regime. To support our claim, the electric bias current dependence of the spin accumulation voltage under the gate voltage applications is investigated in detail and compared to a spin drift diffusion model including the conductance mismatch effect. We proved that the drastic decrease of the mobility and spin lifetime in the Si channel is due to the optical phonon emission at the high electric bias current, which consequently reduced the spin accumulation voltage., Comment: 14 pages, 4 figures

Published
2019
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14. Quantitative and systematic analysis of bias dependence of spin accumulation voltage in a non-degenerate Si spin valve

Author

Lee, Soobeom, Rortais, Fabien, Ohshima, Ryo, Ando, Yuichiro, Miwa, Shinji, Suzuki, Yoshishige, Koike, Hayato, and Shiraishi, Masashi

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

Spin accumulation voltages in a non-degenerate Si spin valve are discussed quantitatively as a function of electric bias current using systematic experiments and model calculations. As an open question in semiconductor spintronics, the origin of the deviation of spin accumulation voltages measured experimentally in a non-degenerate Si spin valve is clarified from that obtained by model calculation using the spin drift diffusion equation including the effect of the spin-dependent interfacial resistance of tunneling barriers. Unlike the case of metallic spin valves, the bias dependence of the resistance-area product for a ferromagnet/MgO/Si interface, resulting in the reappearance of the conductance mismatch, plays a central role to induce the deviation., Comment: 19 pages, 6 figures

Published
2018
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15. Note: Derivative divide, a method for the analysis of broadband ferromagnetic resonance in the frequency domain

Author

Maier-Flaig, Hannes, Goennenwein, Sebastian T. B., Ohshima, Ryo, Shiraishi, Masashi, Gross, Rudolf, Huebl, Hans, and Weiler, Mathias

Subjects
Condensed Matter - Materials Science
Abstract

Broadband ferromagnetic resonance (bbFMR) spectroscopy is an established experimental tool to quantify magnetic properties. Due to frequency-dependent transmission of the microwave setup, bbFMR measurements in the frequency domain require a suitable background removal method. Here, we present a measurement and data analysis protocol that allows to perform quantitative frequency-swept bbFMR measurements without the need for a calibration of the microwave setup. The method, its limitations and advantages are described in detail. Finally the method is applied to evaluate FMR spectra of a permalloy thin film. The extracted material parameters are in very good agreement with those obtained using a conventional analysis in field-space.

Published
2017
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16. Spin injection into silicon detected by broadband ferromagnetic resonance spectroscopy

Author

Ohshima, Ryo, Klingler, Stefan, Dushenko, Sergey, Ando, Yuichiro, Weiler, Mathias, Huebl, Hans, Shinjo, Teruya, Goennenwein, Sebastian T. B., and Shiraishi, Masashi

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

We studied the spin injection in a NiFe(Py)/Si system using broadband ferromagnetic resonance spectroscopy. The Gilbert damping parameter of the Py layer on top of the Si channel was determined as a function of the Si doping concentration and Py layer thickness. For fixed Py thickness we observed an increase of the Gilbert damping parameter with decreasing resistivity of the Si channel. For a fixed Si doping concentration we measured an increasing Gilbert damping parameter for decreasing Py layer thickness. No increase of the Gilbert damping parameter was found Py/Si samples with an insulating interlayer. We attribute our observations to an enhanced spin injection into the low-resistivity Si by spin pumping., Comment: 15 pages, 3 Figures, 2 Tables (to appear Applied Physics Letters)

Published
2017
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17. Quantitative investigation of the inverse Rashba-Edelstein effect in Bi/Ag and Ag/Bi on YIG

Author

Matsushima, Masasyuki, Ando, Yuichiro, Dushenko, Sergey, Ohshima, Ryo, Kumamoto, Ryohei, Shinjo, Teruya, and Shiraishi, Masashi

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The inverse Rashba-Edelstein effect (IREE) is a spin conversion mechanism that recently attracts attention in spintronics and condensed matter physics. In this letter, we report an investigation of the IREE in Bi/Ag by using ferrimagnetic insulator yttrium iron garnet (YIG). We prepared two types of samples with opposite directions of the Rashba field by changing a stacking order of Bi and Ag. An electric current generated by the IREE was observed from both stacks, and an efficiency of spin conversion -characterized by the IREE length- was estimated by taking into account a number of contributions left out in previous studies. This study provides a further insight into the IREE spin conversion mechanism: important step towards achieving efficient spin-charge conversion devices., Comment: 16 pages, 4 figures, Supplemental Materials (To appear in Applied Physics Letters)

Published
2017
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18. Transport and spin conversion of multi-carriers in semimetal bismuth

Author

Emoto, Hiroyuki, Ando, Yuichiro, Eguchi, Gaku, Ohshima, Ryo, Shikoh, Eiji, Fuseya, Yuki, Shinjo, Teruya, and Shiraishi, Masashi

Subjects
Condensed Matter - Materials Science
Abstract

In this paper, we report on the investigation of (1) the transport properties of multi-carriers in semi-metal Bi and (2) the spin conversion physics in this semimetal system in a ferrimagnetic insulator, yttrium-iron-garnet. Hall measurements reveal that electrons and holes co-exist in the Bi, with electrons being the dominant carrier. The results of a spin conversion experiment corroborate the results of the Hall measurement; in addition, the inverse spin Hall effect governs the spin conversion in the semimetal/insulator system. This study provides further insights into spin conversion physics in semimetal systems., Comment: 16 pages, 4 Figures

Published
2016
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19. Strong evidence for d-electron spin transport at room temperature at a LaAlO3/SrTiO3 interface

Author

Ohshima, Ryo, Ando, Yuichiro, Matsuzaki, Kosuke, Susaki, Tomofumi, Weiler, Mathias, Klingler, Stefan, Huebl, Hans, Shikoh, Eiji, Shinjo, Teruya, Goennenwein, Sebastian T. B., and Shiraishi, Masashi

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

A d-orbital electron has an anisotropic electron orbital and is a source of magnetism. The realization of a 2-dimensional electron gas (2DEG) embedded at a LaAlO3/SrTiO3 interface surprised researchers in materials and physical sciences because the 2DEG consists of 3d-electrons of Ti with extraordinarily large carrier mobility, even in the insulating oxide heterostructure. To date, a wide variety of physical phenomena, such as ferromagnetism and the quantum Hall effect, have been discovered in this 2DEG systems, demonstrating the ability of the d-electron 2DEG systems to provide a material platform for the study of interesting physics. However, because of both ferromagnetism and the Rashba field, long-range spin transport and the exploitation of spintronics functions have been believed difficult to implement in the d-electron 2DEG systems. Here, we report the experimental demonstration of room-temperature spin transport in the d-electron-based 2DEG at a LaAlO3/SrTiO3 interface, where the spin relaxation length is ca. exceeding 200 nm. Our finding, which counters the conventional understandings to d-electron 2DEGs, opens a new field of d-electron spintronics. Furthermore, this work highlights a novel spin function in the conductive oxide system., Comment: 30 pages, 5 Figures, 1 Table, including Supplemental Information

Published
2016
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24. Observation of spin-charge conversion in CVD-grown single-layer graphene

Author

Ohshima, Ryo, Sakai, Atsushi, Ando, Yuichiro, Shinjo, Teruya, Kawahara, Kenji, Ago, Hiroki, and Shiraishi, Masashi

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Conversion of pure spin current to charge current in single-layer graphene (SLG) is investigated by using spin pumping. Large-area SLG grown by chemical vapor deposition is used for the conversion. Efficient spin accumulation in SLG by spin pumping enables observing an electromotive force produced by the inverse spin Hall effect (ISHE) of SLG. The spin Hall angle of SLG is estimated to be 6.1*10-7. The observed ISHE in SLG is ascribed to its non-negligible spin-orbit interaction in SLG., Comment: 21 pages, 3 figures

Published
2014
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26. Full calculation of inter-conversion between charge, spin, and heat current using a common partial differential equation platform.

Author

Shigematsu, Ei, Tamura, Eiiti, Ohshima, Ryo, Ando, Yuichiro, and Shiraishi, Masashi

Subjects
PARTIAL differential equations, ANOMALOUS Hall effect, SPINTRONICS, ENHANCED magnetoresistance, HALL effect, QUANTUM Hall effect
Abstract

We present a simple implementation of calculation of spin current profiles using a partial differential equation platform. By solving multiple scalar potentials, spin injection, spin/charge inter-conversion, and thermal spin injection phenomena can be well reproduced numerically. As a demonstration, we show spin current generation and detection in a composite of ferromagnetic, spin conducting, and spin-Hall-metallic materials. Furthermore, we present a model extended to three-dimensionally polarized spin current and describe the matrix for spin/charge current inter-conversion in a conductive ferromagnet, which allows for numerical reproduction of anomalous and planar Hall effects. It is found that the planar Hall voltage is in part generated by spin Hall conductivities, though its magnitude is orders smaller than that induced by the anisotropic magnetoresistance. Our method will contribute to further development of effective and feasible simulations of spin-current-mediated systems. [ABSTRACT FROM AUTHOR]

Published
2022
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29. A circular photogalvanic effect in two-dimensional electron gas on the surface of SrTiO3.

Author

Yamamoto, Mahiro, Nishijima, Taiki, Ohshima, Ryo, Ando, Yuichiro, and Shiraishi, Masashi

Subjects
PHOTOCONDUCTIVITY, TWO-dimensional electron gas, ELECTRON gas, SPIN-orbit interactions, CARRIER density, OPTICAL polarization, CARRIER gas
Abstract

A spin-splitting state due to a Rashba-type spin–orbit interaction is investigated using two-dimensional electron gas (2DEG) at the surface of SrTiO3. The circular photogalvanic effect is utilized to detect the spin-splitting state. Both the polarization and incident light angle dependence of the measured photocurrent generated in the 2DEG unequivocally show the presence of surface spin splitting in the 2DEG, and variation of the carrier densities of the 2DEG provides further supporting evidence. This finding could pave the way for investigating spin textures and spin physics in two-dimensional carrier gas systems. [ABSTRACT FROM AUTHOR]

Published
2024
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31. Precise estimation of spin drift velocity and spin mobility in the absence of synthetic Rashba spin-orbit field in a Si metal-oxide-semiconductor

Author

Inoue, Hajime, Koike, Hayato, Ohshima, Ryo, Ando, Yuichiro, Shiraishi, Masashi, Inoue, Hajime, Koike, Hayato, Ohshima, Ryo, Ando, Yuichiro, and Shiraishi, Masashi

Abstract

The discovery of built-in and synthetic Rashba fields in Si spin channels [S. Lee et al., Nat. Mater. 20, 1228 (2021)] challenged the conventional understanding of spin transport physics in semiconducting materials and forced researchers to reconsider the procedures used for estimating spin drift velocity and spin mobility. A conventional procedure for the estimation involves the detection of the Hanle-type spin precession under the application of an external magnetic field perpendicular to the plane; however, the in-plane effective magnetic fields due to the built-in Rashba fields hamper precise estimation because of the additional spin precession. In this work, we establish a precise method to estimate spin drift velocity and spin mobility, in addition to the spin lifetime and spin diffusion constant, by appropriately tuning the Rashba fields. Beyond the emblematic case of Si, the established method can be applied to other semiconductors, such as Ge and GaAs.

Published
2023

32. All-Electric Spin Device Operation Using the Weyl Semimetal, WTe₂, at Room Temperature

Author

Ohnishi, Kosuke, Aoki, Motomi, Ohshima, Ryo, Shigematsu, Ei, Ando, Yuichiro, Takenobu, Taishi, Shiraishi, Masashi, Ohnishi, Kosuke, Aoki, Motomi, Ohshima, Ryo, Shigematsu, Ei, Ando, Yuichiro, Takenobu, Taishi, and Shiraishi, Masashi

Abstract

Topological quantum materials (TQMs) possess abundant and attractive spin physics, and a Weyl semimetal is the representative material because of the generation of spin polarization that is available for spin devices due to its Weyl nature. Meanwhile, a Weyl semimetal allows the other but unexplored spin polarization due to local symmetry breaking. Here, all-electric spin device operation using a type-II Weyl semimetal, WTe2, at room temperature is reported. The polarization of spins propagating in the all-electric device is perpendicular to the WTe₂ plane, which is ascribed to local in-plane symmetry breaking in WTe₂, yielding the spin polarization creation of propagating charged carriers, namely, the spin-polarized state creation from the nonpolarized state. Systematic control experiments unequivocally negate unexpected artifacts, such as the anomalous Hall effect, the anisotropic magnetoresistance, etc. Creation of all-electric spin devices made of TQMs and their operation at room temperature can pave a new pathway for novel spin devices made of TQMs resilient to thermal fluctuation.

Published
2023

33. Observation of large spin conversion anisotropy in bismuth

Author

Fukumoto, Naoki, primary, Ohshima, Ryo, additional, Aoki, Motomi, additional, Fuseya, Yuki, additional, Matsushima, Masayuki, additional, Shigematsu, Ei, additional, Shinjo, Teruya, additional, Ando, Yuichiro, additional, Sakamoto, Shoya, additional, Shiga, Masanobu, additional, Miwa, Shinji, additional, and Shiraishi, Masashi, additional

Published
2023
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40. Significant suppression of two-magnon scattering in ultrathin Co by controlling the surface magnetic anisotropy at the Co/nonmagnet interfaces

Author

50618361, 30397682, Yoshii, Shugo, Kato, Keisuke, Shigematsu, Ei, Ohshima, Ryo, Ando, Yuichiro, Usami, Koji, Shiraishi, Masashi, 50618361, 30397682, Yoshii, Shugo, Kato, Keisuke, Shigematsu, Ei, Ohshima, Ryo, Ando, Yuichiro, Usami, Koji, and Shiraishi, Masashi

Abstract

To enable suppression of two-magnon scattering (TMS) in nanometer-thick Co (ultrathin Co) layers and realize low-magnon damping in such layers, the magnon damping in ultrathin Co layers grown on various nonmagnetic seed layers with different surface magnetic anisotropy (SMA) energies are investigated. We verify the significantly weak magnon damping realized by varying the seeding layer species used. Although TMS is enhanced in ultrathin Co on Cu and Al seeding layers, the insertion of a Ti seeding layer below the ultrathin Co greatly suppresses the TMS, which is attributed to suppression of the SMA at the interface between Co and Ti. The Gilbert damping constant of the ultrathin Co layer on Ti (3 nm), 0.020, is comparable to the value for bulk Co, although the Co layer thickness here is only 2 nm. Realization of such weak magnon damping can open the door to tunable magnon excitation, thus enabling coupling of magnons with other quanta such as photons, given that the magnetization of ultrathin ferromagnets can be tuned using an external electric field.

Published
2022

43. All‐Electric Spin Device Operation Using the Weyl Semimetal, WTe2, at Room Temperature.

Author

Ohnishi, Kosuke, Aoki, Motomi, Ohshima, Ryo, Shigematsu, Ei, Ando, Yuichiro, Takenobu, Taishi, and Shiraishi, Masashi

Subjects
ANOMALOUS Hall effect, SPIN polarization, ENHANCED magnetoresistance, SYMMETRY breaking
Abstract

Topological quantum materials (TQMs) possess abundant and attractive spin physics, and a Weyl semimetal is the representative material because of the generation of spin polarization that is available for spin devices due to its Weyl nature. Meanwhile, a Weyl semimetal allows the other but unexplored spin polarization due to local symmetry breaking. Here, all‐electric spin device operation using a type‐II Weyl semimetal, WTe2, at room temperature is reported. The polarization of spins propagating in the all‐electric device is perpendicular to the WTe2 plane, which is ascribed to local in‐plane symmetry breaking in WTe2, yielding the spin polarization creation of propagating charged carriers, namely, the spin‐polarized state creation from the nonpolarized state. Systematic control experiments unequivocally negate unexpected artifacts, such as the anomalous Hall effect, the anisotropic magnetoresistance, etc. Creation of all‐electric spin devices made of TQMs and their operation at room temperature can pave a new pathway for novel spin devices made of TQMs resilient to thermal fluctuation. [ABSTRACT FROM AUTHOR]

Published
2023
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47. Modulation of spin-torque ferromagnetic resonance with a nanometer-thick platinum by ionic gating

Author

50618361, 30397682, Ohshima, Ryo, Kohsaka, Yuto, Ando, Yuichiro, Shinjo, Teruya, Shiraishi, Masashi, 50618361, 30397682, Ohshima, Ryo, Kohsaka, Yuto, Ando, Yuichiro, Shinjo, Teruya, and Shiraishi, Masashi

Abstract

The spin Hall effect (SHE) and inverse spin Hall effect (ISHE) have played central roles in modern condensed matter physics especially in spintronics and spin-orbitronics, and much effort has been paid to fundamental and application-oriented research towards the discovery of novel spin–orbit physics and the creation of novel spintronic devices. However, studies on gate-tunability of such spintronics devices have been limited, because most of them are made of metallic materials, where the high bulk carrier densities hinder the tuning of physical properties by gating. Here, we show an experimental demonstration of the gate-tunable spin–orbit torque in Pt/Ni₈₀Fe₂₀ (Py) devices by controlling the SHE using nanometer-thick Pt with low carrier densities and ionic gating. The Gilbert damping parameter of Py and the spin-memory loss at the Pt/Py interface were modulated by ionic gating to Pt, which are compelling results for the successful tuning of spin–orbit interaction in Pt.

Published
2021

48. Enhancement of low-frequency spin-orbit-torque ferromagnetic resonance signals by frequency tuning observed in Pt/Py, Pt/Co, and Pt/Fe bilayers

Author

00879265, 10825011, 30397682, 50618361, Aoki, Motomi, Shigematsu, Ei, Matsushima, Masayuki, Ohshima, Ryo, Honda, Syuta, Shinjo, Teruya, Shiraishi, Masashi, Ando, Yuichiro, 00879265, 10825011, 30397682, 50618361, Aoki, Motomi, Shigematsu, Ei, Matsushima, Masayuki, Ohshima, Ryo, Honda, Syuta, Shinjo, Teruya, Shiraishi, Masashi, and Ando, Yuichiro

Abstract

DC voltages via spin rectification effect (SRE), VDC, under microwave irradiation are investigated for three platinum (Pt)/ferromagnetic metal (FM) bilayer structures: Pt/Ni₈₀Fe₂₀, Pt/Co, and Pt/Fe. At the microwave frequency region lower than the resonant frequency, large VDC is obtained at zero DC magnetic field for all devices. In frequency dependence just around the resonant frequency, sharp rise and drop of magnitude in VDC are observed. These behaviors are well explained by the numerically calculated magnetic susceptibility. It is also found that the magnitude of VDC is strongly dependent on the slope of magnetoresistance spectrum. These findings lead to developments of sensitive detection technique for nano-scale magnetization switching.

Published
2021

49. Spin to charge conversion in Si/Cu/ferromagnet systems investigated by ac inductive measurements

Author

00879265, 10825011, 50618361, 30397682, Shigematsu, Ei, Liensberger, Lukas, Weiler, Mathias, Ohshima, Ryo, Ando, Yuichiro, Shinjo, Teruya, Huebl, Hans, Shiraishi, Masashi, 00879265, 10825011, 50618361, 30397682, Shigematsu, Ei, Liensberger, Lukas, Weiler, Mathias, Ohshima, Ryo, Ando, Yuichiro, Shinjo, Teruya, Huebl, Hans, and Shiraishi, Masashi

Abstract

Semiconductor/ferromagnet hybrid systems are attractive platforms for investigation of spin conversion physics, such as the (inverse) spin Hall effect. However, the superimposed rectification currents originating from anisotropic magnetoresistance have been a serious problem preventing unambiguous detection of dc spin Hall electric signals in semiconductors. In this study, we applied a microwave frequency inductive technique immune to such rectification effects to investigate the spin to charge conversion in heterostructures based on Si, one of the primitive semiconductors. The Si doping dependence of the spin-orbit torque conductivity was obtained for the Si/Cu/NiFe trilayer system. A monotonous modulation of the spin-orbit torque conductivity by doping and relative sign change of spin to charge conversion between the degenerate n- and p-type Si samples were observed. These results unveil spin to charge conversion mechanisms in semiconductor/metal heterostructures and show a pathway for further exploration of spin-conversion physics in metal/semiconductor heterostructures.

Published
2021

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