Controlling Knot Topology in Magnetic Hopfions via Spin-orbit Torque

Abstract

Knots, characterized by topological invariants called the Hopf number H, arise from the intertwining of strings and exhibit diverse configurations. The knot structures have recently been observed in condensed matters, as examplified by a magnetic hopfion, sparking interest in controlling their topology. Here, we show that spin-orbit torque (SOT) enables dynamic manipulation of the Hopf number of magnetic hopfions. We investigate the SOT-driven evolution of hopfions, revealing the splitting of a high-H hopfion into multiple lower-H ones, a process that can be quantified by an effective tension picture. Comparative analysis across different H uncovers a hierarchy of instabilities that dictates these dynamical topological transitions. These findings establish SOT as a powerful tool for controlling hopfion topology, paving the way for potential applications in topological memory devices.

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