High-frequency magnetoacoustic resonance through strain-spin coupling in perpendicular magnetic multilayers

Zhang, De Lin; Zhu, Jin; Qu, Tao; Lattery, Dustin M.; Victora, R. H.; Wang, Xiaojia; Wang, Jian Ping

doi:10.1126/sciadv.abb4607

Cited by 23 publications

(20 citation statements)

References 74 publications

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“…After we have excluded non‐uniformities in magnetic moment density, electron scattering strength, and exchange stiffness as the dominant mechanisms of inversion asymmetry, the lattice strain gradient is left as the most likely symmetry‐breaking mechanism for the bulk dampinglike SOT. Microscopically, a strain gradient can non‐uniformly modify the strengths of the SHE, [ 31–35 ] spin‐orbit interaction, [ 36 ] orbital polarization, [ 37 ] spin states at the Fermi level, [ 37 ] and strain‐spin coupling, [ 38 ] ultimately leading to inversion symmetry breaking in the generation and relaxation of spin current within the sample. As shown in Figure 4c, the lattice constant of the chemically disordered Fe x Pt 1‐ x indeed increases by 2.3% as x from 0.25 to 0.75, [ 39 ] suggesting a very strong strain gradient in the composition‐gradient samples.…”

Section: Resultsmentioning

confidence: 99%

Unveiling the Mechanism of Bulk Spin‐Orbit Torques within Chemically Disordered Fe_xPt_1‐_x Single Layers

Zhu

Ralph

Buhrman

2021

Adv Funct Materials

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The recent discovery of spin‐orbit torques (SOTs) within magnetic single‐layers has attracted attention. However, it remains elusive as to how to understand and how to tune the SOTs. Here, utilizing the single layers of chemically disordered FexPt1‐x, the mechanism of the “unexpected” bulk SOTs is unveiled by studying their dependence on the introduction of a controlled vertical composition gradient and temperature. The bulk dampinglike SOT is found to arise from an imbalanced internal spin current that is transversely polarized and independent of the magnetization orientation. The torque can be strong only in the presence of a vertical composition gradient. The SOT efficiency per electric field is insensitive to temperature but changes sign upon reversal of the orientation of the composition gradient, which is analog to the strain behaviors. These characteristics suggest that the imbalanced internal spin current originates from a bulk spin Hall effect and that the associated inversion asymmetry that allows for a non‐zero net torque is most likely a strain non‐uniformity induced by the composition gradient. The fieldlike SOT is a relatively small bulk effect compared to the dampinglike SOT. This study points to the possibility of developing low‐power single‐layer SOT devices by strain engineering.

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Section: Resultsmentioning

confidence: 99%

Unveiling the Mechanism of Bulk Spin‐Orbit Torques within Chemically Disordered Fe_xPt_1‐_x Single Layers

Zhu

Ralph

Buhrman

2021

Adv Funct Materials

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“…ntense terahertz (THz) radiation has attracted growing interest in the research area of low-frequency excitation dynamics. Since various dynamic processes including lattice vibration, molecular/atom/ion resonance excitation, and electronic spin [1][2][3][4] both coincide with the THz band, brand-new physical perspectives are now opened such as resonant matter control by THz transients [5], strong magnonphonon coupling [6], and electron acceleration and manipulation [7][8][9][10]. Facilitating these intriguing researches requires an easily-accessible, compact, stable, and highrepetition-rate intense THz source.…”

Section: Introductionmentioning

confidence: 99%

Towards High-Repetition-Rate Intense Terahertz Source With Metal Wire-Based Plasma

et al. 2022

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Terahertz radiation can provide unprecedented vistas in physical studies such as transient matter state control and advanced free-electron manipulation. Here, we present one feasible path towards high-repetition-rate, intense THz sources by combining the wire-based THz source on a consecutively running, wire-conveying tape design. The proof-of-principle experimental results show an upper 30 mW average THz power output under 1 kHz laser excitation, which presents the first high-repetition-rate, and most importantly, portable and application in handy THz source that is generated by solid plasmas. The generated THz pulses are characterized with a 0.3 THz center frequency and ~0.3 THz bandwidth. We believe this tabletop laser-driven highrepetition-rate THz source will open a new door for THz and related interdisciplinary sciences.

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“…Thus, the nanocomposite and nanogranular ferromagnetic film structures fabricated at low-temperature conditions have attracted significant attention because of the decoupling of the intergranular interaction that could enhance the signal-to-noise ratio; therefore, they are considered more favorable for the next generation magnetic storage media [13][14][15][16][17][18][19][20][21][22][23]. Many attempts have been made to propose the effect of top or under layers; the additive effect of metal oxides and nitride elements is a successful method to control the chemical ordering, microstructure, magnetic coupling, and crystalline orientation of the L1 0 magnetic thin films to meet the requirements of industrial manufacture, especially in technologically important perpendicular magnetic materials for multifunctional device applications [24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42]. Recently, the spin Hall effect (SHE)-induced perpendicular magnetization reversal behavior is with pay significant attention due to its potential for future low-power memory and logic devices.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, the spin Hall effect (SHE)-induced perpendicular magnetization reversal behavior is with pay significant attention due to its potential for future low-power memory and logic devices. So, the spin Hall systems and related perpendicular magnetic tunnel junctions could pave the way towards more actual spin-orbit torque-based non-volatile magnetic memory and strain-spin coupling for applications of programmable logic devices [36][37][38][39]42].…”

Section: Introductionmentioning

confidence: 99%

Controlled Magnetic Isolation and Decoupling of Perpendicular FePt Films by Capping Ultrathin Cu(002) Nano-Islands

et al. 2021

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This study investigated the ultrathin Cu(002) capping nano-island effects on the magnetic characterizations and microstructure of epitaxial FePt(001) films directly fabricated on MgO(001) substrates at the relatively low temperature of 300 °C via electron-beam deposition. The enhancement of the coercivity is attributed to the lowered exchange coupling of FePt magnetic grains that begun from Cu atom behavior of spreading in many directions mainly along grain boundaries due to its lower surface energy than that of pure Fe or Pt. The measurement of angular-dependent coercivity shows a tendency of a domain-wall motion shift toward the rotation of the reverse-domain type upon the thickness of the Cu capping nano-island layer atop the FePt films. The intergranular interaction was clarified by the Kelly–Henkel plot, which indicated that there was strong exchange coupling (positive δM) between neighboring grains in the FePt continuous films without Cu capping nano-islands. On the other hand, a negative δM value was gained when the FePt films were capped with a Cu(002) single layer, indicating that the Cu capping layer can be used to control the strength of intergrain exchange coupling between the adjacent FePt grains and thicker Cu(002) capping nano-islands toward magnetic isolation; thus, there was an existence of dipole interaction in our designed Cu/FePt composite structure of stacked films.

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High-frequency magnetoacoustic resonance through strain-spin coupling in perpendicular magnetic multilayers

Cited by 23 publications

References 74 publications

Unveiling the Mechanism of Bulk Spin‐Orbit Torques within Chemically Disordered Fe_xPt_1‐_x Single Layers

Unveiling the Mechanism of Bulk Spin‐Orbit Torques within Chemically Disordered Fe_xPt_1‐_x Single Layers

Towards High-Repetition-Rate Intense Terahertz Source With Metal Wire-Based Plasma

Controlled Magnetic Isolation and Decoupling of Perpendicular FePt Films by Capping Ultrathin Cu(002) Nano-Islands

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High-frequency magnetoacoustic resonance through strain-spin coupling in perpendicular magnetic multilayers

Cited by 23 publications

References 74 publications

Unveiling the Mechanism of Bulk Spin‐Orbit Torques within Chemically Disordered FexPt1‐x Single Layers

Unveiling the Mechanism of Bulk Spin‐Orbit Torques within Chemically Disordered FexPt1‐x Single Layers

Towards High-Repetition-Rate Intense Terahertz Source With Metal Wire-Based Plasma

Controlled Magnetic Isolation and Decoupling of Perpendicular FePt Films by Capping Ultrathin Cu(002) Nano-Islands

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About

Unveiling the Mechanism of Bulk Spin‐Orbit Torques within Chemically Disordered Fe_xPt_1‐_x Single Layers

Unveiling the Mechanism of Bulk Spin‐Orbit Torques within Chemically Disordered Fe_xPt_1‐_x Single Layers