Anomalous Hall conductivity from the dipole mode of spin-orbit-coupled cold-atom systems

E. van der Bijl; R.A. Duine

doi:10.1103/PhysRevLett.107.195302

Anomalous Hall conductivity from the dipole mode of spin-orbit-coupled cold-atom systems

E. van der Bijl, R.A. Duine

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Motivated by recent experiments by Lin et al., [ Nature (London) 471 83 (2011)] that engineered spin-orbit coupling in ultracold mixtures of bosonic atoms, we study the dipole oscillation of trapped spin-orbit-coupled noncondensed Bose and Fermi gases. We find that different directions of oscillation are coupled by the spin-orbit interactions. The phase difference between oscillatory motion in orthogonal directions and the trapping frequencies of the modes are shown to be related to the anomalous Hall conductivity. Our results can be used to experimentally determine the anomalous Hall conductivity for cold-atom systems

Original language	English
Article number	195302
Number of pages	5
Journal	Physical Review Letters
Volume	107
Issue number	19
DOIs	https://doi.org/10.1103/PhysRevLett.107.195302
Publication status	Published - 2011

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AnomalousHallVanderBijl
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title = "Anomalous Hall conductivity from the dipole mode of spin-orbit-coupled cold-atom systems",

abstract = "Motivated by recent experiments by Lin et al., [ Nature (London) 471 83 (2011)] that engineered spin-orbit coupling in ultracold mixtures of bosonic atoms, we study the dipole oscillation of trapped spin-orbit-coupled noncondensed Bose and Fermi gases. We find that different directions of oscillation are coupled by the spin-orbit interactions. The phase difference between oscillatory motion in orthogonal directions and the trapping frequencies of the modes are shown to be related to the anomalous Hall conductivity. Our results can be used to experimentally determine the anomalous Hall conductivity for cold-atom systems",

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N2 - Motivated by recent experiments by Lin et al., [ Nature (London) 471 83 (2011)] that engineered spin-orbit coupling in ultracold mixtures of bosonic atoms, we study the dipole oscillation of trapped spin-orbit-coupled noncondensed Bose and Fermi gases. We find that different directions of oscillation are coupled by the spin-orbit interactions. The phase difference between oscillatory motion in orthogonal directions and the trapping frequencies of the modes are shown to be related to the anomalous Hall conductivity. Our results can be used to experimentally determine the anomalous Hall conductivity for cold-atom systems

AB - Motivated by recent experiments by Lin et al., [ Nature (London) 471 83 (2011)] that engineered spin-orbit coupling in ultracold mixtures of bosonic atoms, we study the dipole oscillation of trapped spin-orbit-coupled noncondensed Bose and Fermi gases. We find that different directions of oscillation are coupled by the spin-orbit interactions. The phase difference between oscillatory motion in orthogonal directions and the trapping frequencies of the modes are shown to be related to the anomalous Hall conductivity. Our results can be used to experimentally determine the anomalous Hall conductivity for cold-atom systems

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DO - 10.1103/PhysRevLett.107.195302

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Anomalous Hall conductivity from the dipole mode of spin-orbit-coupled cold-atom systems

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