Related papers: Phases, instabilities and excitations in a two-component lattice model with photon-mediated interactions

Phases, instabilities and excitations in a two-component lattice model with photon-mediated interactions

URL: http://arxiv.org/abs/2210.11313v1
Date: Thu, 20 Oct 2022 14:45:01 GMT
Title: Phases, instabilities and excitations in a two-component lattice model with photon-mediated interactions
Authors: Leon Carl, Rodrigo Rosa-Medina, Sebastian D. Huber, Tilman Esslinger, Nishant Dogra, Tena Dubcek
Abstract summary: We study a two-component spin Bose-Hubbard system with cavity-mediated interactions. The interplay of different energy scales yields a rich phase diagram with superfluid and insulating phases. The studied lattice model can be readily realized in cold-atom experiments with optical cavities.
Score: 0.12233362977312942
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Engineering long-range interacting spin systems with ultra cold atoms offers the possibility to explore exotic magnetically ordered phases in strongly-correlated scenarios. Quantum gases in optical cavities provide a versatile experimental platform to further engineer photon-mediated interactions and access the underlying microscopic processes by probing the cavity field. Here, we study a two-component spin Bose-Hubbard system with cavity-mediated interactions. We provide a comprehensive overview of its phase diagram and transitions in experimentally relevant regimes. The interplay of different energy scales yields a rich phase diagram with superfluid and insulating phases exhibiting density modulation or spin ordering. In particular, the combined effect of contact and global-range interactions gives rise to an antiferromagnetically ordered phase for arbitrarily small spin-dependent light-matter coupling, while long-range and inter-spin contact interactions introduce regions of instability and phase separation in the phase diagram. We further study the low energy excitations above the antiferrogmagnetic phase. Besides particle-hole branches, it hosts spin-exchange excitations with a tunable energy gap. The studied lattice model can be readily realized in cold-atom experiments with optical cavities.

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