Litcius/Paper detail

Orbital torque originating from orbital Hall effect in Zr

Riko Fukunaga, Satoshi Haku, Hiroki Hayashi, Kazuya Ando

2023Physical Review Research71 citationsDOIOpen Access PDF

Abstract

We investigate current-induced torques generated by Zr. We show that the generation efficiency of the current-induced torque increases with increasing the thickness of the Zr layer in ${\mathrm{Ni}}_{81}{\mathrm{Fe}}_{19}/\mathrm{Zr}$ and Ni/Zr bilayers, which indicates that the observed current-induced torque originates from the bulk of the Zr layer. We find that the sign of the current-induced torques is opposite to that expected from the spin Hall effect but is consistent with that expected from the orbital Hall effect in the Zr layer. Furthermore, we find that the torque efficiency increases with increasing the thickness of the ferromagnetic layer, which is consistent with the prediction of long-range orbital transport in ferromagnets. These observations demonstrate that the orbital Hall effect in the Zr layer is the main source of the current-induced torque. This finding highlights the important role of orbital transport in generating current-induced torques, advancing the understanding of angular momentum dynamics in solid-state devices with $4d$ transition metals.

Topics & Concepts

Condensed matter physicsFerromagnetismTorqueAngular momentumCurrent (fluid)Spin-transfer torqueHall effectSpin (aerodynamics)Layer (electronics)Materials sciencePhysicsNanotechnologyElectrical resistivity and conductivityMagnetizationQuantum mechanicsThermodynamicsMagnetic fieldMagnetic properties of thin filmsQuantum and electron transport phenomenaAdvanced Memory and Neural Computing