TY - JOUR
T1 - Geometrical Hall effect and momentum-space Berry curvature from spin-reversed band pairs
AU - Hirschberger, Max
AU - Nomura, Yusuke
AU - Mitamura, Hiroyuki
AU - Miyake, Atsushi
AU - Koretsune, Takashi
AU - Kaneko, Yoshio
AU - Spitz, Leonie
AU - Taguchi, Yasujiro
AU - Matsuo, Akira
AU - Kindo, Koichi
AU - Arita, Ryotaro
AU - Tokunaga, Masashi
AU - Tokura, Yoshinori
N1 - Funding Information:
Acknowledgments. We have benefited from discussions with N. Nagaosa, K. Ueda, I. Belopolski, and J. Masell. M.H. was supported as a Humboldt/JSPS International Research Fellow (18F18804). Y.N. acknowledges JSPS KAKENHI Grants-in-Aid for Scientific Research (Grants No. 16H06345, No. 17K14336, and No. 18H01158). L.S. was funded by the German Academic Exchange Service (DAAD) via a PROMOS scholarship awarded by the German Federal Ministry of Education and Research (BMBF). This work was partially supported by JST CREST Grant No. JPMJCR1874 (Japan).
Publisher Copyright:
© 2021 American Physical Society.
PY - 2021/1/25
Y1 - 2021/1/25
N2 - When nanometric, noncoplanar spin textures with scalar spin chirality (SSC) are coupled to itinerant electrons, they endow the quasiparticle wave functions with a gauge field, termed Berry curvature, in a way that bears analogy to relativistic spin-orbit coupling (SOC). The resulting deflection of moving charge carriers is termed the geometrical (or topological) Hall effect. Previous experimental studies modeled this signal as a real-space motion of wave packets under the influence of a quantum-mechanical phase. In contrast, we here compare the modification of Bloch waves themselves and of their energy dispersion due to SOC and SSC. Using the canted pyrochlore ferromagnet Nd2Mo2O7 as a model compound, our transport experiments and first-principles calculations show that SOC impartially mixes electronic bands with equal or opposite spin, while SSC is much more effective for opposite-spin band pairs.
AB - When nanometric, noncoplanar spin textures with scalar spin chirality (SSC) are coupled to itinerant electrons, they endow the quasiparticle wave functions with a gauge field, termed Berry curvature, in a way that bears analogy to relativistic spin-orbit coupling (SOC). The resulting deflection of moving charge carriers is termed the geometrical (or topological) Hall effect. Previous experimental studies modeled this signal as a real-space motion of wave packets under the influence of a quantum-mechanical phase. In contrast, we here compare the modification of Bloch waves themselves and of their energy dispersion due to SOC and SSC. Using the canted pyrochlore ferromagnet Nd2Mo2O7 as a model compound, our transport experiments and first-principles calculations show that SOC impartially mixes electronic bands with equal or opposite spin, while SSC is much more effective for opposite-spin band pairs.
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U2 - 10.1103/PhysRevB.103.L041111
DO - 10.1103/PhysRevB.103.L041111
M3 - Article
AN - SCOPUS:85100237373
SN - 2469-9950
VL - 103
JO - Physical Review B-Condensed Matter
JF - Physical Review B-Condensed Matter
IS - 4
M1 - L041111
ER -