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Controlling higher-orbital quantum phases of ultracold atoms via coupling to optical cavities

Orbital degree of freedom plays an important role in understanding exotic phenomena of strongly correlated materials. We study strongly correlated ultracold bosonic gases coupled to a high-finesse cavity, pumped by a blue-detuned laser in the transverse direction. Based on an extended Bose-Hubbard model with parameters adapted to recent experiments, we find that by tuning the reflection of pump laser, atoms can be selectively transferred to the odd-parity $p$-orbital, or to even-parity $d$-orbital band of a two-dimensional square lattice, accompanied with cavity-photon excitations. By interacting with cavity field, atoms self-organize to form stable higher-orbital superfluid and Mott-insulating phases with orbital-density waves, as a result of cavity induced orbital-flip processes. Our study opens the route to manipulate orbital degrees of freedom in strongly correlated quantum gases via coupling to optical cavities.

preprint2021arXivOpen access
Hui TanJinsen HanWei ZhengJianmin YuanYongqiang Li
physics.atom-phcond-mat.str-elcond-mat.quant-gas
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Hui TanJinsen HanWei ZhengJianmin YuanYongqiang Li

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