Abstract
We show that coupling ultracold atoms in optical lattices to quantized modes of an optical cavity leads to quantum phases of matter, which at the same time posses properties of systems with both short- and long-range interactions. This opens perspectives for novel quantum simulators of finite-range interacting systems, even though the light-induced interaction is global (i.e. infinitely long range). This is achieved by spatial structuring of the global light-matter coupling at a microscopic scale. Such simulators can directly benefit from the collective enhancement of the global light-matter interaction and constitute an alternative to standard approaches using Rydberg atoms or polar molecules. The system in the steady state of light induces effective many-body interactions that change the landscape of the phase diagram of the typical Bose-Hubbard model. Therefore, the system can support non-trivial superfluid states, bosonic dimer, trimers, etc. states and supersolid phases depending on the choice of the wavelength and pattern of the light with respect to the classical optical lattice potential. We find that by carefully choosing the system parameters one can investigate diverse strongly correlated physics with the same setup, i.e., modifying the geometry of light beams. In particular, we present the interplay between the density and bond (or matter-wave coherence) interactions. We show how to tune the effective interaction length in such a hybrid system with both short-range and global interactions.
Highlights
Ultracold gases loaded in an optical lattice are the ideal tool for studying the quantum degenerate regime of matter
Quantum light induces in its steady state an effective structured long-range interaction
This steady-state effective many-body interaction changes the energetic landscape at the quantum level because atoms see a different energy landscape that depends on the cavity-pump detunings and the chosen spatial arrangement of the cavities and light pumped into the system
Summary
Ultracold gases loaded in an optical lattice are the ideal tool for studying the quantum degenerate regime of matter. In contrast to these examples, we show that loading an optical lattice inside a cavity allows us to engineer synthetic many-body interactions with an arbitrary spatial profile These interactions are mediated by the light field and do not depend on fundamental processes, making them extremely tunable and suitable for realizing quantum simulations of manybody long-range Hamiltonians. We show how one can construct arbitrary interactions using the light-induced structures that are formed These effective interactions will be useful for the purpose of quantum simulation of finite-range interactions among other possible applications.
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