Mathieu Barbier scite author profile

We investigate the possibility of realizing supersolid quantum phases in bosonic Rydberg-excited quantum lattice gases in the presence of non-unitary processes, by simulating the dynamical evolution starting from initial preparation in non-dissipative equilibrium states. Within Gutzwiller theory, we first analyze the many-body ground-state of a bosonic Rydberg-excited quantum gas in a two dimensional optical lattice for variable atomic hopping rates and Rabi detunings. Furthermore, we perform time evolution of different supersolid phases using the Lindblad-master equation. With the inclusion of two different non-unitary processes, namely spontaneous decay from a Rydberg state to the ground state and dephasing of the addressed Rydberg state, we study the effect of nonunitary processes on those quantum phases and observe long-lived states in the presence of decay and dephasing. We find that long-lived supersolid quantum phases are observable within a range of realistic decay and dephasing rates, while high rates cause any initial configuration to homogenize quickly, preventing possible supersolid formation.

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Supersolid phases of Rydberg-excited bosons on a triangular lattice

Panas

Barbier

Geißler

et al. 2019

Phys. Rev. A

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Recent experiments with ultracold Rydberg-excited atoms have shown that long-range interactions can give rise to spatially ordered structures. Observation of crystalline phases in a system with Rydberg atoms loaded into an optical lattice seems also within reach. Here we investigate a bosonic model on a triangular lattice suitable for description of such experiments. Numerical simulations based on bosonic dynamical mean-field theory reveal a rich phase diagram with different supersolid phases. Comparison with the results obtained for a square lattice geometry shows qualitatively similar results in a wide range of parameters, however, on a triangular lattice we do not observe the checkerboard supersolid. Moreover, unlike on a square lattice we did not find a phase transition from uniform superfluid to supersolid induced by increase of the hopping amplitude on a triangular lattice. Based on our results we propose an intuitive interpretation of the nature of different supersolid phases. We also propose parameters for the experimental realization.

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Topological Mott transition in a Weyl-Hubbard model: Dynamical mean-field theory study

et al. 2021

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Supersolid phases of ultracold bosons trapped in optical lattices dressed with Rydberg p states

2022

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Mathieu Barbier

Extended Bose-Hubbard models with Rydberg macrodimer dressing

Decay-dephasing-induced steady states in bosonic Rydberg-excited quantum gases in an optical lattice

Supersolid phases of Rydberg-excited bosons on a triangular lattice

Topological Mott transition in a Weyl-Hubbard model: Dynamical mean-field theory study

Supersolid phases of ultracold bosons trapped in optical lattices dressed with Rydberg p states

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