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Topological Hall effect arising from the mesoscopic and microscopic non-coplanar magnetic structure in MnBi

Yangkun He, Sebastian Schneider, Toni Helm, Jacob Gayles, Daniel Wolf, Ivan Soldatov, Horst Borrmann, Walter Schnelle, Rudolf Schaefer, Gerhard H. Fecher, Bernd Rellinghaus, Claudia Felser

2022Acta Materialia23 citationsDOIOpen Access PDF

Abstract

The topological Hall effect (THE), induced by the Berry curvature that originates from non-zero scalar spin chirality, is an important feature for mesoscopic topological structures, such as skyrmions. However, the THE might also arise from other microscopic non-coplanar spin structures in the lattice. Thus, the origin of the THE inevitably needs to be determined to fully understand skyrmions and find new host materials. Here, we examine the Hall effect in both, bulk- and micron-sized lamellar samples of MnBi. The sample size affects the temperature and field range in which the THE is detectable. Although a bulk sample exhibits the THE only upon exposure to weak fields in the easy-cone state, in micron-sized lamella the THE exists across a wide temperature range and occurs at fields near saturation. Our results show that both the non-coplanar spin structure in the lattice and topologically non-trivial skyrmion bubbles are responsible for the THE, and that the dominant mechanism depends on the sample size. Hence, the magnetic phase diagram for MnBi is size-dependent. Our study provides an example in which the THE is simultaneously induced by two mechanisms, and builds a bridge between mesoscopic and microscopic magnetic structures.

Topics & Concepts

Mesoscopic physicsCondensed matter physicsSkyrmionMaterials scienceSpin structureMagnetic fieldHall effectPhase diagramBerry connection and curvatureTopology (electrical circuits)PhysicsAntiferromagnetismPhase (matter)Geometric phaseQuantum mechanicsMathematicsCombinatoricsMagnetic properties of thin filmsPhysics of Superconductivity and MagnetismTopological Materials and Phenomena