Electric field effect on the magnetic domain wall creep velocity in Pt/Co/Pd structures with different Co thicknesses

小山 知弘*; 家田 淳一; 千葉 大地*

Applied Physics Letters, 116(9), p.092405_1 - 092405_5, 2020/03

AA2019-0550.pdf:0.91MB

https://doi.org/10.1063/1.5143970

The electric field (EF) modulation of magnetic domain wall (DW) creep velocity in Pt/Co/Pd structure with perpendicular magnetic anisotropy (MA) has been studied. The structures with different Co thickness up to nm are investigated. In all samples, applying a gate voltage induces a clear change in . Thicker samples provide a higher modulation efficiency, and the modulation magnitude of more than a factor of 100 times is observed in the thickest of 0.98 nm. The parameter characterizing the creep motion is significantly affected by the EF, resulting in the modulation of . Unlike the case, the MA modulation efficiency decreases with increasing . The present results are discussed based on the EF-induced change in the interfacial Dzyaloshinskii-Moriya interaction (iDMI), which has been recently demonstrated in the same structure, and dependence of the DW energy. The dependence of the modulation suggests that the EF effect on the iDMI is more important than the MA.

Spin-motive force due to a gyrating magnetic vortex

田辺 賢士*; 千葉 大地*; 大江 純一郎*; 葛西 伸哉*; 河野 日出夫*; Barnes, S. E.*; 前川 禎通; 小林 研介*; 小野 輝男*

Nature Communications (Internet), 3, p.845_1 - 845_5, 2012/05

https://doi.org/10.1038/ncomms1824

A change of magnetic flux through a circuit induces an electromotive force. By analogy, a recently predicated force that results from the motion of non-uniform spin structures has been termed the spin-motive force. Although recent experiments seem to confirm its presence, a direct signature of the spin-motive force has remained elusive. Here we report the observation of a real-time spin-motive force produced by the gyration of a magnetic vortex core. We report a good agreement between the experimental results, theory, and micromagnetic simulations, which, taken as a whole, provide strong evidence in favour of a spin-motive force.