6533b7d7fe1ef96bd1267b56
RESEARCH PRODUCT
Field-driven domain wall motion under a bias current in the creep andflow regimes in Pt/[CoSiB/Pt](N) nanowires
Kab-jin KimChun-yeol YouTae-woo KimYoungha ChoiMyung-hwa JungYoko YoshimuraKyujoon LeeTeruo Onosubject
MultidisciplinaryMaterials scienceMagnetic domainCondensed matter physicsSpintronicsMagnetic devices02 engineering and technology021001 nanoscience & nanotechnology01 natural sciencesArticleAmorphous solidMagnetic fieldDomain wall (magnetism)Creep0103 physical sciencesElectronic devicesElectric current010306 general physics0210 nano-technologyAnisotropySimulationdescription
AbstractThe dynamics of magnetic domain wall (DW) in perpendicular magnetic anisotropy Pt/[CoSiB/Pt]N nanowires was studied by measuring the DW velocity under a magnetic field (H) and an electric current (J) in two extreme regimes of DW creep and flow. Two important findings are addressed. One is that the field-driven DW velocity increases with increasing N in the flow regime, whereas the trend is inverted in the creep regime. The other is that the sign of spin current-induced effective field is gradually reversed with increasing N in both DW creep and flow regimes. To reveal the underlying mechanism of new findings, we performed further experiment and micromagnetic simulation, from which we found that the observed phenomena can be explained by the combined effect of the DW anisotropy, Dzyaloshinskii-Moriya interaction, spin-Hall effect, and spin-transfer torques. Our results shed light on the mechanism of DW dynamics in novel amorphous PMA nanowires, so that this work may open a path to utilize the amorphous PMA in emerging DW-based spintronic devices.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-03-31 |