Angle-dependence and optimal design for magnetic bubblecade with maximum speed
Duck-Ho Kim, Kyoung-Woong Moon, Sang-Cheol Yoo, Dae-Yun Kim,, Byoung-Chul Min, Chanyong Hwang, Sug-Bong Choe

TL;DR
This paper investigates the angle-dependent behavior of magnetic bubblecade motion driven by tilted alternating magnetic fields, providing an optimal configuration and a simple formula for maximum speed to aid device design.
Contribution
It introduces the optimal tilt angle for maximum bubblecade speed and derives an analytical formula based on domain-wall creep theory, advancing magnetic domain-wall motion control.
Findings
Maximum bubblecade speed occurs at a specific tilt angle.
The speed dependence on tilt angle is well explained by domain-wall creep theory.
A simple formula predicts the optimal tilt angle based on magnetic field amplitude.
Abstract
Unidirectional magnetic domain-wall motion is a key concept underlying next-generation application devices. Such motion has been recently demonstrated by applying an alternating magnetic field, resulting in the coherent unidirectional motion of magnetic bubbles. Here we report the optimal configuration of applied magnetic field for the magnetic bubblecade, the coherent unidirectional motion of magnetic bubbles, driven by a tilted alternating magnetic field. The tilted alternating magnetic field induces asymmetric expansion and shrinkage of the magnetic bubbles under the influence of the Dzyaloshinskii-Moriya interaction, resulting in continuous shift of the bubbles in time. By realizing the magnetic bubblecade in PtCoPt films, we find that the bubblecade speed is sensitive to the tilt angle with a maximum at an angle, which can be explained well by a simple analytical form within the…
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Taxonomy
TopicsMagnetic properties of thin films · Advanced Memory and Neural Computing · Characterization and Applications of Magnetic Nanoparticles
