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Proximity effects in cold atom artificial graphene

Quantum Gases 2017-08-01 v2 Materials Science Strongly Correlated Electrons Atomic Physics Quantum Physics

Abstract

Cold atoms in an optical lattice with brick-wall geometry have been used to mimic graphene, a two-dimensional material with characteristic Dirac excitations. Here we propose to bring such artificial graphene into the proximity of a second atomic layer with a square lattice geometry. For non-interacting fermions, we find that such bilayer system undergoes a phase transition from a graphene-like semi-metal phase, characterized by a band structure with Dirac points, to a gapped band insulator phase. In the presence of attractive interactions between fermions with pseudospin-1/2 degree of freedom, a competition between semi-metal and superfluid behavior is found at the mean-field level. Using the quantum Monte Carlo method, we also investigate the case of strong repulsive interactions. In the Mott phase, each layer exhibits a different amount of long-range magnetic order. Upon coupling both layers, a valence-bond crystal is formed at a critical coupling strength. Finally, we discuss how these bilayer systems could be realized in existing cold atom experiments.

Keywords

Cite

@article{arxiv.1608.02868,
  title  = {Proximity effects in cold atom artificial graphene},
  author = {Tobias Grass and Ravindra W. Chhajlany and Leticia Tarruell and Vittorio Pellegrini and Maciej Lewenstein},
  journal= {arXiv preprint arXiv:1608.02868},
  year   = {2017}
}

Comments

8 figures

R2 v1 2026-06-22T15:16:04.284Z