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Observation of large spin conversion anisotropy in bismuth.

Naoki FukumotoRyo OhshimaMotomi AokiYuki FuseyaMasayuki MatsushimaEi ShigematsuTeruya ShinjoYuichiro AndoShoya SakamotoMasanobu ShigaShinji MiwaMasashi Shiraishi
Published in: Proceedings of the National Academy of Sciences of the United States of America (2023)
While the effective g -factor can be anisotropic due to the spin-orbit interaction (SOI), its existence in solids cannot be simply asserted from a band structure, which hinders progress on studies from such viewpoints. The effective g -factor in bismuth (Bi) is largely anisotropic; especially for holes at T -point, the effective g -factor perpendicular to the trigonal axis is negligibly small (<0.112), whereas the effective g -factor along the trigonal axis is very large (62.7). We clarified in this work that the large anisotropy of effective g -factor gives rise to the large spin conversion anisotropy in Bi from experimental and theoretical approaches. Spin-torque ferromagnetic resonance was applied to estimate the spin conversion efficiency in rhombohedral (110) Bi to be 17 to 27%, which is unlike the negligibly small efficiency in Bi(111). Harmonic Hall measurements support the large spin conversion efficiency in Bi(110). A large spin conversion anisotropy as the clear manifestation of the anisotropy of the effective g -factor is observed. Beyond the emblematic case of Bi, our study unveiled the significance of the effective g -factor anisotropy in condensed-matter physics and can pave a pathway toward establishing novel spin physics under g -factor control.
Keyphrases
  • room temperature
  • density functional theory
  • single molecule
  • transition metal