Three-dimensional topological orbital Hall effect caused by magnetic hopfions

TL;DR

This paper predicts a unique three-dimensional orbital Hall effect caused by magnetic hopfions, providing a potential electronic signature for their detection and opening new avenues for spin-orbitronic applications.

Contribution

It introduces the concept of a three-dimensional orbital Hall effect induced by hopfions, linking topological invariants to observable orbital transport phenomena.

Findings

Hopfions generate a transverse orbital current under electric fields.

The orbital Hall effect distinguishes hopfions from similar magnetic textures.

The effect relates to the Hopf index, a three-dimensional topological invariant.

Abstract

Magnetic hopfions are non-collinear spin textures that are characterized by an integer topological invariant, called Hopf index. The three-dimensional magnetic solitons can be thought of as a tube with a twisted magnetization that has been closed at both ends to form a torus. The tube consists of a magnetic whirl called in-plane skyrmion or bimeron. Although hopfions have been observed by microscopy techniques, their detection remains challenging as they lack an electronic hallmark so far. Here we predict a three-dimensional orbital Hall effect caused by hopfion textures: When an electric field is applied, the hopfion generates a transverse current of orbital angular momentum. The effect arises due to the local emergent field that gives rise to in-plane and out-of-plane orbital Hall conductivities. This orbital Hall response can be seen as a hallmark of hopfions and allows us to distinguish them from other textures, like skyrmioniums, that look similar in real-space microscopy experiments. While the two-dimensional topological invariant of a skyrmion determines its topological Hall transport, the unique three-dimensional topological orbital Hall effect can be identified with the three-dimensional topological invariant that is the Hopf index. Our results make hopfions attractive for spin-orbitronic applications because their orbital signatures allow for their detection in devices and give rise to large orbital torques.