Title :
Micromagnetic Modeling on Current-Induced Multiple Domain-Wall Motion in Permalloy Nanotubes
Author :
Feng-Sheng Wu ; Horng, Lance ; Yee-Mou Kao ; Jong-Ching Wu
Author_Institution :
Dept. of Phys., Nat. Changhua Univ. of Educ., Changhua, Taiwan
Abstract :
We performed micromagnetic modeling on moving multiple data bits (2-64 bits) in permalloy (Ni80Fe20) cylindrical nanotubes (PCNTs) and numerically investigated the domain-wall movement, which relies on the applied current, the Gilbert damping factor α, and radii ratio β. It was found that current-driven multiple transverse domain walls (TDWs) motion in nanotubes with an outer diameter below 25 nm and β > 0.33 was characteristic of an exceptional massless mobility. We observed that the velocity of TDWs confined in nanotubes, which was in proportion to the applied current, depended mainly on the sizes of the tubes, and α, but was independent of the number of TDWs. The obtained results offer a way to design the magnetization structures for the DW-based devices by controlling the nanotube geometric and material parameters.
Keywords :
Permalloy; damping; magnetic domain walls; magnetisation; micromagnetics; nanotubes; Gilbert damping factor; Ni80Fe20; current-induced multiple domain-wall motion; magnetization structure; massless mobility; micromagnetic modeling; moving multiple data bit; nanotube geometric parameter; nanotube material parameter; permalloy cylindrical nanotube; permalloy nanotube; transverse domain wall; Electron tubes; Magnetic domain walls; Magnetic domains; Magnetic multilayers; Magnetization; Materials; Nanotubes; Domain-wall motion; Landau???Lifshitz???Gilbert (LLG) equation; magnetic nanotube;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2014.2325022
