We study the spin Hall magnetoresistance effect in ferrimagnet/normal metal bilayers, comparing the response in collinear and canted magnetic phases. In the collinear magnetic phase, in which the sublattice magnetic moments are all aligned along the same axis, we observe the conventional spin Hall magnetoresistance. In contrast, in the canted phase, the magnetoresistance changes sign. Using atomistic spin simulations and x-ray absorption experiments, we can understand these observations in terms of the magnetic field and temperature dependent orientation of magnetic moments on different magnetic sublattices. This enables a magnetotransport based investigation of noncollinear magnetic textures

Andrei Rogalev

Benjamin A. Piot

Fabrice Wilhelm

Francois Guillou

G. F. Dionne

Gerrit E. W. Bauer

Hans Huebl

I. M. Miron

Joseph Barker

Katharina Ollefs

Kathrin Ganzhorn

Matthias Althammer

Matthias Opel

Richard Schlitz

Rudolf Gross

Sebastian T. B. Goennenwein

Stephan Geprägs

arXiv

International audienceWe study the spin Hall magnetoresistance effect in ferrimagnet/normal metal bilayers, comparing the response in collinear and canted magnetic phases. In the collinear magnetic phase, in which the sublattice magnetic moments are all aligned along the same axis, we observe the conventional spin Hall magnetoresistance. In contrast, in the canted phase, the magnetoresistance changes sign. Using atomistic spin simulations and x-ray absorption experiments, we can understand these observations in terms of the magnetic field and temperature dependent orientation of magnetic moments on different magnetic sublattices. This enables a magnetotransport based investigation of noncollinear magnetic textures

Ganzhorn, Kathrin

Barker, Joseph

Schlitz, Richard

Piot, Benjamin

Ollefs, Katharina

Guillou, Francois

Wilhelm, Fabrice

Rogalev, Andrei

Opel, Matthias

Althammer, Matthias

Geprägs, Stephan

Huebl, Hans

Gross, Rudolf

Bauer, Gerrit

Goennenwein, Sebastian

Hal - Université Grenoble Alpes

Spin Hall magnetoresistance in a canted ferrimagnet

Ganzhorn, K

Barker, J

Schlitz, R

Piot, BA

Ollefs, K

Guillou, F

Wilhelm, F

Rogalev, A

Opel, M

Althammer, M

Geprägs, S

Huebl, H

Gross, R

Bauer, GEW

Goennenwein, STB

White Rose Research Online

We study the spin Hall magnetoresistance effect in ferrimagnet/normal metal bilayers, comparing the response in collinear and canted magnetic phases. In the collinear magnetic phase, in which the sublattice magnetic moments are all aligned along the same axis, we observe the conventional spin Hall magnetoresistance. In contrast, in the canted phase, the magnetoresistance changes sign. Using atomistic spin simulations and x-ray absorption experiments, we can understand these observations in terms of the magnetic field and temperature dependent orientation of magnetic moments on different magnetic sublattices. This enables a magnetotransport based investigation of noncollinear magnetic textures.</p

Piot, Benjamin A.

Guillou, F.

Bauer, G.E.

NARCIS 

HAL - Normandie Université

Crossref

Hal-Diderot

We study the spin Hall magnetoresistance effect in ferrimagnet/normal metal bilayers, comparing the response in collinear and canted magnetic phases. In the collinear magnetic phase, in which the sublattice magnetic moments are all aligned along the same axis, we observe the conventional spin Hall magnetoresistance. In contrast, in the canted phase, the magnetoresistance changes sign. Using atomistic spin simulations and x-ray absorption experiments, we can understand these observations in terms of the magnetic field and temperature dependent orientation of magnetic moments on different magnetic sublattices. This enables a magnetotransport based investigation of noncollinear magnetic textures.QN/Bauer Grou

Spin Hall magnetoresistance in a canted ferrimagnet

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Hal - Université Grenoble Alpes

White Rose Research Online

NARCIS

HAL - Normandie Université

Crossref

White Rose Research Online

Hal-Diderot

TU Delft Repository