Chiral Domain Walls Induced by Radially Magnetized Nanotube Geometry

We theoretically investigate chiral domain walls (DWs) formed in radially magnetized nanotubes with perpendicular magnetic anisotropy (PMA). Unlike tubes with an easy axis of magnetization oriented in other directions, radially magnetized tubes exhibit geometrical effects arising not only from exchange interactions but also from magnetostatic interactions, which lead to Dzyaloshinskii-Moriya interaction (DMI)-like effects. We derive expressions for the effective magnetic fields acting on DWs within PMA nanotubes and quantify SOT-driven DW motion using an analytical one-dimensional model, which is validated by micromagnetic simulations. Our results show that the DMI-like field due to magnetostatic interactions can be as significantly as the contribution of the material-induced DMI in nanotubes with diameters below 100$\,$nm. This implies that the direction and speed of DW motion in PMA nanotubes could differ from those observed in nanoribbons composed of the same material. Furthermore, we demonstrate that DW velocity can be effectively controlled by adjusting the tube diameter and exchange stiffness constant of the magnetic layer, rather than relying solely on the material-induced DMI. These insights are expected to greatly expand the potential applications of PMA nanotube-based DW devices.