Abstract
Spin Hall magnetoresistance (SMR) refers to a resistance change in a metallic film reflecting the magnetization direction of a magnet attached to the film. The mechanism of this phenomenon is spin exchange between conduction-electron spins and magnetization at the interface. SMR has been used to read out information written in a small magnet and to detect magnetization dynamics, but it has been limited to magnets; magnetic ordered phases or instability of magnetic phase transition has been believed to be indispensable. Here, we report the observation of SMR in a paramagnetic insulator Gd$_{3}$Ga$_{5}$O$_{12}$ (GGG) without spontaneous magnetization combined with a Pt film. The paramagnetic SMR can be attributed to spin-transfer torque acting on localized spins in GGG. We determine the efficiencies of spin torque and spin-flip scattering at the Pt/GGG interface, and demonstrate these quantities can be tuned with external magnetic fields. The results clarify the mechanism of spin-transport at a metal/paramagnetic insulator interface, which gives new insight into the spintronic manipulation of spin states in paramagnetic systems.
Highlights
Spintronics [1,2] aims to add new functionalities to the conventional electronics using interconversion of spin angular momentum between different carriers in solids
We report the observation of the spin Hall magnetoresistance (SMR) in a paramagnetic insulator
By measuring the transverse resistance in a Pt/Gd3Ga5O12 (GGG) system at low temperatures, paramagnetic SMR is found to appear with an intensity that increases with the magnetic field aligning GGG’s spins
Summary
Spintronics [1,2] aims to add new functionalities to the conventional electronics using interconversion of spin angular momentum between different carriers in solids. By measuring the transverse resistance in a Pt/Gd3Ga5O12 (GGG) system at low temperatures, paramagnetic SMR is found to appear with an intensity that increases with the magnetic field aligning GGG’s spins. The observed correlation between SMR/SHAHE and magnetization indicates that the field-induced magnetization plays a significant role in the spin transport at the Pt/GGG interface.
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