Berry-phase interpretation of thin-film micromagnetism | Zendy

Ralph Skomski | Zendy; Balamurugan Balasubramanian | Zendy; Ahsan Ullah | Zendy; Christian Binek | Zendy; D. J. Sellmyer | Zendy

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Berry-phase interpretation of thin-film micromagnetism

Author(s) -

Ralph Skomski,

Balamurugan Balasubramanian,

Ahsan Ullah,

Christian Binek,

D. J. Sellmyer

Publication year - 2022

Publication title -

aip advances

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.421

H-Index - 58

ISSN - 2158-3226

DOI - 10.1063/9.0000332

Subject(s) - condensed matter physics , geometric phase , hall effect , electron , physics , magnetization , lorentz transformation , micromagnetics , phase (matter) , magnetic field , lorentz force , field (mathematics) , magnetoresistance , thin film , quantum mechanics , mathematics , pure mathematics

Magnetic flux densities ( B-fields) and field intensities ( H-fields) in thin films are investigated from the viewpoints of Berry phase and topological Hall effect. The well-known origin of the topological Hall effect is an emergent B-field originating from the Berry phase of conduction electrons, but Maxwell’s equations predict the relevant perpendicular component B z to be zero. This paradox is solved by treating the electrons as point-like objects in Lorentz cavities. These cavities can also be used to interpret magnetization measurements in the present and other contexts, but structural and magnetic inhomogeneities lead to major modifications of the Lorentz-hole picture.

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