Dependence of inverse-spin Hall effect and spin-rectified voltage on tantalum thickness in Ta/CoFeB bilayer structure

Ta-layer thickness (tTa) dependence of the measured DC voltage V from the inverse-spin Hall effect (ISHE) in Ta/CoFeB bilayer structure is experimentally investigated using the ferromagnetic resonance in the TE011 resonant cavity. The ISHE signals excluding the spin-rectified effect (SRE) were separ...

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Bibliographic Details
Published in:Applied physics letters 2015-01, Vol.106 (3)
Main Authors: Kim, Sang-Il, Kim, Dong-Jun, Seo, Min-Su, Park, Byong-Guk, Park, Seung-Young
Format: Article
Language:English
Subjects:
Applied physics
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
COBALT COMPOUNDS
Dependence
Deviation
Diffusion length
Electric potential
Electromagnetism
FERROMAGNETIC RESONANCE
Ferromagnetism
HALL EFFECT
IRON BORIDES
LAYERS
MAGNETIZATION
SPIN
TANTALUM
THICKNESS
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Summary:Ta-layer thickness (tTa) dependence of the measured DC voltage V from the inverse-spin Hall effect (ISHE) in Ta/CoFeB bilayer structure is experimentally investigated using the ferromagnetic resonance in the TE011 resonant cavity. The ISHE signals excluding the spin-rectified effect (SRE) were separated from the fitted curve of V against tTa. For tTa ≈ λTa (Ta-spin diffusion length = 2.7 nm), the deviation in ISHE voltage VISH between the experimental and theoretical values is significantly increased because of the large SRE contribution, which also results in a large deviation in the spin Hall angle θSH (from 10% to 40%). However, when tTa ≫ λTa, the VISH values are consistent with theoretical values because the SRE terms become negligible, which subsequently improves the accuracy of the obtained θSH within 4% deviation. The results will provide an outline for an accurate estimation of the θSH for materials with small λ value, which would be useful for utilizing the spin Hall effect in a 3-terminal spintronic devices in which magnetization can be controlled by in-plane current.
ISSN:0003-6951
1077-3118
DOI:10.1063/1.4906487