Magnetic domain-wall motion twisted by nanoscale probe-induced spin transfer

J. Wang; L. S. Xie; C. S. Wang; H. Z. Zhang; L. Shu; J. Bai; Y. S. Chai; X. Zhao; J. C. Nie; C. B. Cao; C. Z. Gu; C. M. Xiong; Y. Sun; J. Shi; S. Salahuddin; K. Xia; C. W. Nan; J. X. Zhang

doi:10.1103/PhysRevB.90.224407

Magnetic domain-wall motion twisted by nanoscale probe-induced spin transfer

J. Wang, L. S. Xie, C. S. Wang, H. Z. Zhang, L. Shu, J. Bai, Y. S. Chai, X. Zhao, J. C. Nie, C. B. Cao, C. Z. Gu, C. M. Xiong, Y. Sun, J. Shi, S. Salahuddin, K. Xia, C. W. Nan, J. X. Zhang

材料学院

科研成果: 期刊稿件 › 文章 › 同行评审

16 引用（Scopus）

摘要

A method for deterministic control of magnetism using an electrical stimulus is highly desired for the new generation of magnetoelectronic devices. Much effort has been focused on magnetic domain-wall (DW) motion manipulated by a successive injection of spin-polarized current into a magnetic nanostructure. However, an integrant high-threshold current density of 1011∼1012A/m2 inhibits the integration with low-energy-cost technology. Here, we report an approach to manipulate a single magnetic domain wall with a perpendicular anisotropy in a manganite/dielectric/metal capacitor using a probe-induced spin displacement. A spin-transfer torque (STT) occurs in the strongly correlated manganite film during the spin injection into the capacitor from the nanoscale magnetized tip with an ultralow voltage of 0.1 V, where a lower bound of the estimated threshold spin-polarized current density is ∼108A/m2 at the tip/manganite interface. The dynamic of DW motions are analyzed using the Landau-Lifshitz-Gilbert method. This probe-voltage-controlled DW motion, at an ambient condition, demonstrates a critical framework for the fundamental understanding of the manipulation of the nanomagnet systems with low-energy consumption.

源语言	英语
文章编号	224407
期刊	Physical Review B - Condensed Matter and Materials Physics
卷	90
期	22
DOI	https://doi.org/10.1103/PhysRevB.90.224407
出版状态	已出版 - 5 12月 2014

联合国可持续发展目标

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10.1103/PhysRevB.90.224407

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Wang, J., Xie, L. S., Wang, C. S., Zhang, H. Z., Shu, L., Bai, J., Chai, Y. S., Zhao, X., Nie, J. C., Cao, C. B., Gu, C. Z., Xiong, C. M., Sun, Y., Shi, J., Salahuddin, S., Xia, K., Nan, C. W., & Zhang, J. X. (2014). Magnetic domain-wall motion twisted by nanoscale probe-induced spin transfer. Physical Review B - Condensed Matter and Materials Physics, 90(22), 文章 224407. https://doi.org/10.1103/PhysRevB.90.224407

@article{2815a962dfb84b93ab4d3800c26d6dce,

title = "Magnetic domain-wall motion twisted by nanoscale probe-induced spin transfer",

abstract = "A method for deterministic control of magnetism using an electrical stimulus is highly desired for the new generation of magnetoelectronic devices. Much effort has been focused on magnetic domain-wall (DW) motion manipulated by a successive injection of spin-polarized current into a magnetic nanostructure. However, an integrant high-threshold current density of 1011∼1012A/m2 inhibits the integration with low-energy-cost technology. Here, we report an approach to manipulate a single magnetic domain wall with a perpendicular anisotropy in a manganite/dielectric/metal capacitor using a probe-induced spin displacement. A spin-transfer torque (STT) occurs in the strongly correlated manganite film during the spin injection into the capacitor from the nanoscale magnetized tip with an ultralow voltage of 0.1 V, where a lower bound of the estimated threshold spin-polarized current density is ∼108A/m2 at the tip/manganite interface. The dynamic of DW motions are analyzed using the Landau-Lifshitz-Gilbert method. This probe-voltage-controlled DW motion, at an ambient condition, demonstrates a critical framework for the fundamental understanding of the manipulation of the nanomagnet systems with low-energy consumption.",

author = "J. Wang and Xie, {L. S.} and Wang, {C. S.} and Zhang, {H. Z.} and L. Shu and J. Bai and Chai, {Y. S.} and X. Zhao and Nie, {J. C.} and Cao, {C. B.} and Gu, {C. Z.} and Xiong, {C. M.} and Y. Sun and J. Shi and S. Salahuddin and K. Xia and Nan, {C. W.} and Zhang, {J. X.}",

note = "Publisher Copyright: {\textcopyright} 2014 American Physical Society.",

year = "2014",

month = dec,

day = "5",

doi = "10.1103/PhysRevB.90.224407",

language = "English",

volume = "90",

journal = "Physical Review B - Condensed Matter and Materials Physics",

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publisher = "American Physical Society",

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Wang, J, Xie, LS, Wang, CS, Zhang, HZ, Shu, L, Bai, J, Chai, YS, Zhao, X, Nie, JC, Cao, CB, Gu, CZ, Xiong, CM, Sun, Y, Shi, J, Salahuddin, S, Xia, K, Nan, CW & Zhang, JX 2014, 'Magnetic domain-wall motion twisted by nanoscale probe-induced spin transfer', Physical Review B - Condensed Matter and Materials Physics, 卷 90, 号码 22, 224407. https://doi.org/10.1103/PhysRevB.90.224407

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T1 - Magnetic domain-wall motion twisted by nanoscale probe-induced spin transfer

AU - Wang, J.

AU - Xie, L. S.

AU - Wang, C. S.

AU - Zhang, H. Z.

AU - Shu, L.

AU - Bai, J.

AU - Chai, Y. S.

AU - Zhao, X.

AU - Nie, J. C.

AU - Cao, C. B.

AU - Gu, C. Z.

AU - Xiong, C. M.

AU - Sun, Y.

AU - Shi, J.

AU - Salahuddin, S.

AU - Xia, K.

AU - Nan, C. W.

AU - Zhang, J. X.

PY - 2014/12/5

Y1 - 2014/12/5

N2 - A method for deterministic control of magnetism using an electrical stimulus is highly desired for the new generation of magnetoelectronic devices. Much effort has been focused on magnetic domain-wall (DW) motion manipulated by a successive injection of spin-polarized current into a magnetic nanostructure. However, an integrant high-threshold current density of 1011∼1012A/m2 inhibits the integration with low-energy-cost technology. Here, we report an approach to manipulate a single magnetic domain wall with a perpendicular anisotropy in a manganite/dielectric/metal capacitor using a probe-induced spin displacement. A spin-transfer torque (STT) occurs in the strongly correlated manganite film during the spin injection into the capacitor from the nanoscale magnetized tip with an ultralow voltage of 0.1 V, where a lower bound of the estimated threshold spin-polarized current density is ∼108A/m2 at the tip/manganite interface. The dynamic of DW motions are analyzed using the Landau-Lifshitz-Gilbert method. This probe-voltage-controlled DW motion, at an ambient condition, demonstrates a critical framework for the fundamental understanding of the manipulation of the nanomagnet systems with low-energy consumption.

AB - A method for deterministic control of magnetism using an electrical stimulus is highly desired for the new generation of magnetoelectronic devices. Much effort has been focused on magnetic domain-wall (DW) motion manipulated by a successive injection of spin-polarized current into a magnetic nanostructure. However, an integrant high-threshold current density of 1011∼1012A/m2 inhibits the integration with low-energy-cost technology. Here, we report an approach to manipulate a single magnetic domain wall with a perpendicular anisotropy in a manganite/dielectric/metal capacitor using a probe-induced spin displacement. A spin-transfer torque (STT) occurs in the strongly correlated manganite film during the spin injection into the capacitor from the nanoscale magnetized tip with an ultralow voltage of 0.1 V, where a lower bound of the estimated threshold spin-polarized current density is ∼108A/m2 at the tip/manganite interface. The dynamic of DW motions are analyzed using the Landau-Lifshitz-Gilbert method. This probe-voltage-controlled DW motion, at an ambient condition, demonstrates a critical framework for the fundamental understanding of the manipulation of the nanomagnet systems with low-energy consumption.

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U2 - 10.1103/PhysRevB.90.224407

DO - 10.1103/PhysRevB.90.224407

M3 - Article

AN - SCOPUS:84915760026

SN - 1098-0121

VL - 90

JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 22

M1 - 224407

ER -

Magnetic domain-wall motion twisted by nanoscale probe-induced spin transfer

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