核心概念
The planar Hall conductivity in Bi2Se3/EuS interfaces exhibits distinct anisotropic features depending on the orientation and magnitude of the proximity-induced magnetic moment in EuS, as well as the presence of a topological spin texture such as magnetic skyrmions.
摘要
The paper investigates the electronic transport properties, particularly the planar Hall effect, in Bi2Se3/EuS heterostructures. The authors use a realistic model Hamiltonian and a semi-classical Boltzmann transport formalism to analyze the system.
Key highlights:
- The proximity coupling between the topological insulator Bi2Se3 and the ferromagnetic insulator EuS can lead to a canting of the Eu magnetic moments, which in turn modifies the electronic structure of the Bi2Se3 surface states.
- The anisotropy in the planar Hall conductivity arises from the asymmetric Berry curvature of the gapped topological surface states, which depends on the orientation and magnitude of the proximity-induced Eu magnetic moment.
- For a fixed Eu moment orientation, the planar Hall conductivity can exhibit symmetric, antisymmetric or anisotropic behavior with respect to the in-plane magnetic field angle, depending on the canting angles.
- When the Eu moment is free to reorient with the applied in-plane field, the planar Hall conductivity is dominant in a specific range of field values, determined by the critical fields.
- The authors also explore the possibility of a topological Hall effect arising from magnetic skyrmions that can form at the Bi2Se3/EuS interface due to the interplay of ferromagnetic exchange, Dzyaloshinskii-Moriya interaction, and the perpendicular alignment of the Eu moment.
統計資料
The Eu magnetic moment m is varied from 0 to 6.9 μB.
The critical in-plane magnetic field values Bc' and Bc are in the range of 10-30 mT.
The initial polar canting angle θm0 of the Eu moment is varied from 0° to 45°.
引述
"The anisotropy in the planar Hall conductivity arises from the asymmetric Berry curvature of the gapped topological surface states."
"The PHC is dominant for the in-plane field in the second regime, |Bc'| ≤ |Bin| ≤ |Bc|."
"Magnetic skyrmions can appear naturally when the Eu moment is aligned out of the interface plane, as found in the first-principle analysis of the interface."