Spin-orbit-splitting-driven nonlinear Hall effect in NbIrTe4

Ji Eun Lee; Aifeng Wang; Shuzhang Chen; Minseong Kwon; Jinwoong Hwang; Minhyun Cho; Ki Hoon Son; Dong Soo Han; Jun Woo Choi; Young Duck Kim; Sung Kwan Mo; Cedomir Petrovic; Choongyu Hwang; Se Young Park; Chaun Jang; Hyejin Ryu

doi:10.1038/s41467-024-47643-4

Spin-orbit-splitting-driven nonlinear Hall effect in NbIrTe₄

Ji Eun Lee, Aifeng Wang, Shuzhang Chen, Minseong Kwon, Jinwoong Hwang, Minhyun Cho, Ki Hoon Son, Dong Soo Han, Jun Woo Choi, Young Duck Kim, Sung Kwan Mo, Cedomir Petrovic, Choongyu Hwang, Se Young Park, Chaun Jang, Hyejin Ryu

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6 Citations (Scopus)

Abstract

The Berry curvature dipole (BCD) serves as a one of the fundamental contributors to emergence of the nonlinear Hall effect (NLHE). Despite intense interest due to its potential for new technologies reaching beyond the quantum efficiency limit, the interplay between BCD and NLHE has been barely understood yet in the absence of a systematic study on the electronic band structure. Here, we report NLHE realized in NbIrTe₄ that persists above room temperature coupled with a sign change in the Hall conductivity at 150 K. First-principles calculations combined with angle-resolved photoemission spectroscopy (ARPES) measurements show that BCD tuned by the partial occupancy of spin-orbit split bands via temperature is responsible for the temperature-dependent NLHE. Our findings highlight the correlation between BCD and the electronic band structure, providing a viable route to create and engineer the non-trivial Hall effect by tuning the geometric properties of quasiparticles in transition-metal chalcogen compounds.

Original language	English
Article number	3971
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-47643-4
Publication status	Published - Dec 2024

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© The Author(s) 2024.

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title = "Spin-orbit-splitting-driven nonlinear Hall effect in NbIrTe4",

abstract = "The Berry curvature dipole (BCD) serves as a one of the fundamental contributors to emergence of the nonlinear Hall effect (NLHE). Despite intense interest due to its potential for new technologies reaching beyond the quantum efficiency limit, the interplay between BCD and NLHE has been barely understood yet in the absence of a systematic study on the electronic band structure. Here, we report NLHE realized in NbIrTe4 that persists above room temperature coupled with a sign change in the Hall conductivity at 150 K. First-principles calculations combined with angle-resolved photoemission spectroscopy (ARPES) measurements show that BCD tuned by the partial occupancy of spin-orbit split bands via temperature is responsible for the temperature-dependent NLHE. Our findings highlight the correlation between BCD and the electronic band structure, providing a viable route to create and engineer the non-trivial Hall effect by tuning the geometric properties of quasiparticles in transition-metal chalcogen compounds.",

author = "Lee, {Ji Eun} and Aifeng Wang and Shuzhang Chen and Minseong Kwon and Jinwoong Hwang and Minhyun Cho and Son, {Ki Hoon} and Han, {Dong Soo} and Choi, {Jun Woo} and Kim, {Young Duck} and Mo, {Sung Kwan} and Cedomir Petrovic and Choongyu Hwang and Park, {Se Young} and Chaun Jang and Hyejin Ryu",

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AU - Lee, Ji Eun

AU - Wang, Aifeng

AU - Chen, Shuzhang

AU - Kwon, Minseong

AU - Hwang, Jinwoong

AU - Cho, Minhyun

AU - Son, Ki Hoon

AU - Han, Dong Soo

AU - Choi, Jun Woo

AU - Kim, Young Duck

AU - Mo, Sung Kwan

AU - Petrovic, Cedomir

AU - Hwang, Choongyu

AU - Park, Se Young

AU - Jang, Chaun

AU - Ryu, Hyejin

PY - 2024/12

Y1 - 2024/12

N2 - The Berry curvature dipole (BCD) serves as a one of the fundamental contributors to emergence of the nonlinear Hall effect (NLHE). Despite intense interest due to its potential for new technologies reaching beyond the quantum efficiency limit, the interplay between BCD and NLHE has been barely understood yet in the absence of a systematic study on the electronic band structure. Here, we report NLHE realized in NbIrTe4 that persists above room temperature coupled with a sign change in the Hall conductivity at 150 K. First-principles calculations combined with angle-resolved photoemission spectroscopy (ARPES) measurements show that BCD tuned by the partial occupancy of spin-orbit split bands via temperature is responsible for the temperature-dependent NLHE. Our findings highlight the correlation between BCD and the electronic band structure, providing a viable route to create and engineer the non-trivial Hall effect by tuning the geometric properties of quasiparticles in transition-metal chalcogen compounds.

AB - The Berry curvature dipole (BCD) serves as a one of the fundamental contributors to emergence of the nonlinear Hall effect (NLHE). Despite intense interest due to its potential for new technologies reaching beyond the quantum efficiency limit, the interplay between BCD and NLHE has been barely understood yet in the absence of a systematic study on the electronic band structure. Here, we report NLHE realized in NbIrTe4 that persists above room temperature coupled with a sign change in the Hall conductivity at 150 K. First-principles calculations combined with angle-resolved photoemission spectroscopy (ARPES) measurements show that BCD tuned by the partial occupancy of spin-orbit split bands via temperature is responsible for the temperature-dependent NLHE. Our findings highlight the correlation between BCD and the electronic band structure, providing a viable route to create and engineer the non-trivial Hall effect by tuning the geometric properties of quasiparticles in transition-metal chalcogen compounds.

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VL - 15

JO - Nature Communications

JF - Nature Communications

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Spin-orbit-splitting-driven nonlinear Hall effect in NbIrTe₄

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