Room-temperature high spin–orbit torque due to quantum confinement in sputtered Bi xSe(1–x) films

Mahendra Dc; Roberto Grassi; Jun Yang Chen; Mahdi Jamali; Danielle Reifsnyder Hickey; Delin Zhang; Zhengyang Zhao; Hongshi Li; P. Quarterman; Yang Lv; Mo Li; Aurelien Manchon; K. Andre Mkhoyan; Tony Low; Jian Ping Wang

doi:10.1038/s41563-018-0136-z

Room-temperature high spin–orbit torque due to quantum confinement in sputtered Bi_xSe_(1–x) films

Mahendra Dc, Roberto Grassi, Jun Yang Chen, Mahdi Jamali, Danielle Reifsnyder Hickey, Delin Zhang, Zhengyang Zhao, Hongshi Li, P. Quarterman, Yang Lv, Mo Li, Aurelien Manchon, K. Andre Mkhoyan, Tony Low, Jian Ping Wang

Chemistry

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272 Scopus citations

Abstract

The spin–orbit torque (SOT) that arises from materials with large spin–orbit coupling promises a path for ultralow power and fast magnetic-based storage and computational devices. We investigated the SOT from magnetron-sputtered Bi_xSe_(1–x) thin films in Bi_xSe_(1–x)/Co₂₀Fe₆₀B₂₀ heterostructures by using d.c. planar Hall and spin-torque ferromagnetic resonance (ST-FMR) methods. Remarkably, the spin torque efficiency (θ_S) was determined to be as large as 18.62 ± 0.13 and 8.67 ± 1.08 using the d.c. planar Hall and ST-FMR methods, respectively. Moreover, switching of the perpendicular CoFeB multilayers using the SOT from the Bi_xSe_(1–x) was observed at room temperature with a low critical magnetization switching current density of 4.3 × 10⁵ A cm^–2. Quantum transport simulations using a realistic sp³ tight-binding model suggests that the high SOT in sputtered Bi_xSe_(1–x) is due to the quantum confinement effect with a charge-to-spin conversion efficiency that enhances with reduced size and dimensionality. The demonstrated θ_S, ease of growth of the films on a silicon substrate and successful growth and switching of perpendicular CoFeB multilayers on Bi_xSe_(1–x) films provide an avenue for the use of Bi_xSe_(1–x) as a spin density generator in SOT-based memory and logic devices.

Original language	English (US)
Pages (from-to)	800-807
Number of pages	8
Journal	Nature Materials
Volume	17
Issue number	9
DOIs	https://doi.org/10.1038/s41563-018-0136-z
State	Published - Sep 1 2018

All Science Journal Classification (ASJC) codes

Chemistry(all)
Materials Science(all)
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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@article{dbd8902aff284703a9a5dbcd416fa389,

title = "Room-temperature high spin–orbit torque due to quantum confinement in sputtered Bi xSe(1–x) films",

abstract = "The spin–orbit torque (SOT) that arises from materials with large spin–orbit coupling promises a path for ultralow power and fast magnetic-based storage and computational devices. We investigated the SOT from magnetron-sputtered BixSe(1–x) thin films in BixSe(1–x)/Co20Fe60B20 heterostructures by using d.c. planar Hall and spin-torque ferromagnetic resonance (ST-FMR) methods. Remarkably, the spin torque efficiency (θS) was determined to be as large as 18.62 ± 0.13 and 8.67 ± 1.08 using the d.c. planar Hall and ST-FMR methods, respectively. Moreover, switching of the perpendicular CoFeB multilayers using the SOT from the BixSe(1–x) was observed at room temperature with a low critical magnetization switching current density of 4.3 × 105 A cm–2. Quantum transport simulations using a realistic sp3 tight-binding model suggests that the high SOT in sputtered BixSe(1–x) is due to the quantum confinement effect with a charge-to-spin conversion efficiency that enhances with reduced size and dimensionality. The demonstrated θS, ease of growth of the films on a silicon substrate and successful growth and switching of perpendicular CoFeB multilayers on BixSe(1–x) films provide an avenue for the use of BixSe(1–x) as a spin density generator in SOT-based memory and logic devices.",

author = "Mahendra Dc and Roberto Grassi and Chen, {Jun Yang} and Mahdi Jamali and {Reifsnyder Hickey}, Danielle and Delin Zhang and Zhengyang Zhao and Hongshi Li and P. Quarterman and Yang Lv and Mo Li and Aurelien Manchon and Mkhoyan, {K. Andre} and Tony Low and Wang, {Jian Ping}",

note = "Funding Information: We thank P. Crowell for proofreading the manuscript and M. Kawaguchi for helpful discussions on data analysis. We also thank T. Peterson and G. Stecklein for their help with the PPMS measurements. This work was supported by C-SPIN, one of six STARnet programme research centres. This work utilized (1) the College of Science and Engineering (CSE) Characterization Facility, University of Minnesota (UM), supported in part by the NSF through the UMN MRSEC programme (no. DMR-1420013), and (2) the CSE Minnesota Nano Center, UM, supported in part by the NSF through the NNIN programme. A.M. was supported by the King Abdullah University of Science and Technology (KAUST). Publisher Copyright: {\textcopyright} 2018, The Author(s).",

year = "2018",

month = sep,

day = "1",

doi = "10.1038/s41563-018-0136-z",

language = "English (US)",

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pages = "800--807",

journal = "Nature Materials",

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T1 - Room-temperature high spin–orbit torque due to quantum confinement in sputtered Bi xSe(1–x) films

AU - Dc, Mahendra

AU - Grassi, Roberto

AU - Chen, Jun Yang

AU - Jamali, Mahdi

AU - Reifsnyder Hickey, Danielle

AU - Zhang, Delin

AU - Zhao, Zhengyang

AU - Li, Hongshi

AU - Quarterman, P.

AU - Lv, Yang

AU - Li, Mo

AU - Manchon, Aurelien

AU - Mkhoyan, K. Andre

AU - Low, Tony

AU - Wang, Jian Ping

N1 - Funding Information: We thank P. Crowell for proofreading the manuscript and M. Kawaguchi for helpful discussions on data analysis. We also thank T. Peterson and G. Stecklein for their help with the PPMS measurements. This work was supported by C-SPIN, one of six STARnet programme research centres. This work utilized (1) the College of Science and Engineering (CSE) Characterization Facility, University of Minnesota (UM), supported in part by the NSF through the UMN MRSEC programme (no. DMR-1420013), and (2) the CSE Minnesota Nano Center, UM, supported in part by the NSF through the NNIN programme. A.M. was supported by the King Abdullah University of Science and Technology (KAUST). Publisher Copyright: © 2018, The Author(s).

PY - 2018/9/1

Y1 - 2018/9/1

N2 - The spin–orbit torque (SOT) that arises from materials with large spin–orbit coupling promises a path for ultralow power and fast magnetic-based storage and computational devices. We investigated the SOT from magnetron-sputtered BixSe(1–x) thin films in BixSe(1–x)/Co20Fe60B20 heterostructures by using d.c. planar Hall and spin-torque ferromagnetic resonance (ST-FMR) methods. Remarkably, the spin torque efficiency (θS) was determined to be as large as 18.62 ± 0.13 and 8.67 ± 1.08 using the d.c. planar Hall and ST-FMR methods, respectively. Moreover, switching of the perpendicular CoFeB multilayers using the SOT from the BixSe(1–x) was observed at room temperature with a low critical magnetization switching current density of 4.3 × 105 A cm–2. Quantum transport simulations using a realistic sp3 tight-binding model suggests that the high SOT in sputtered BixSe(1–x) is due to the quantum confinement effect with a charge-to-spin conversion efficiency that enhances with reduced size and dimensionality. The demonstrated θS, ease of growth of the films on a silicon substrate and successful growth and switching of perpendicular CoFeB multilayers on BixSe(1–x) films provide an avenue for the use of BixSe(1–x) as a spin density generator in SOT-based memory and logic devices.

AB - The spin–orbit torque (SOT) that arises from materials with large spin–orbit coupling promises a path for ultralow power and fast magnetic-based storage and computational devices. We investigated the SOT from magnetron-sputtered BixSe(1–x) thin films in BixSe(1–x)/Co20Fe60B20 heterostructures by using d.c. planar Hall and spin-torque ferromagnetic resonance (ST-FMR) methods. Remarkably, the spin torque efficiency (θS) was determined to be as large as 18.62 ± 0.13 and 8.67 ± 1.08 using the d.c. planar Hall and ST-FMR methods, respectively. Moreover, switching of the perpendicular CoFeB multilayers using the SOT from the BixSe(1–x) was observed at room temperature with a low critical magnetization switching current density of 4.3 × 105 A cm–2. Quantum transport simulations using a realistic sp3 tight-binding model suggests that the high SOT in sputtered BixSe(1–x) is due to the quantum confinement effect with a charge-to-spin conversion efficiency that enhances with reduced size and dimensionality. The demonstrated θS, ease of growth of the films on a silicon substrate and successful growth and switching of perpendicular CoFeB multilayers on BixSe(1–x) films provide an avenue for the use of BixSe(1–x) as a spin density generator in SOT-based memory and logic devices.

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JF - Nature Materials

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ER -

Room-temperature high spin–orbit torque due to quantum confinement in sputtered Bi_xSe_(1–x) films

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