Valley-dependent gauge fields for ultracold atoms in square optical superlattices

We propose an experimental scheme to realize the valley-dependent gauge fields for ultracold fermionic atoms trapped in a state-dependent square optical lattice. Our scheme relies on two sets of Raman laser beams to engineer the hopping between adjacent sites populated by two-component fermionic ato...

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Bibliographic Details
Published inarXiv.org
Main Authors Dan-Wei, Zhang, Chuan-Jia Shan, Feng, Mei, Mou, Yang, Rui-Qiang, Wang, Shi-Liang, Zhu
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 04.01.2014
Subjects
Dirac equation
Graphene
Laser beams
Optical lattices
Particle beams
Particle spin
Physics - Mesoscale and Nanoscale Physics
Physics - Quantum Gases
Physics - Quantum Physics
Raman lasers
Strain gauges
Superlattices
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Summary:We propose an experimental scheme to realize the valley-dependent gauge fields for ultracold fermionic atoms trapped in a state-dependent square optical lattice. Our scheme relies on two sets of Raman laser beams to engineer the hopping between adjacent sites populated by two-component fermionic atoms. One set of Raman beams are used to realize a staggered \pi-flux lattice, where low energy atoms near two inequivalent Dirac points should be described by the Dirac equation for spin-1/2 particles. Another set of laser beams with proper Rabi frequencies are added to further modulate the atomic hopping parameters. The hopping modulation will give rise to effective gauge potentials with opposite signs near the two valleys, mimicking the interesting strain-induced pseudo-gauge fields in graphene. The proposed valley-dependent gauge fields are tunable and provide a new route to realize quantum valley Hall effects and atomic valleytronics.
ISSN:2331-8422
DOI:10.48550/arxiv.1309.7711