Achievable Three-dimensional Quantum Ising Model Simulated with a Mixture of Ultracold Neutral Atoms

The low-energy effective model of a double-species Fermi-Hubbard (DSFH) model is analysed numerically with exact diagonalization method. When the lowest-energy subspace of the DSFH model is a Mott insulator of fermion pairs, the low-energy effective model is an exact antiferromagnetic Ising model with both transverse and longitudinal fields. Similarly, a ferromagnetic Ising model can be realized with a double-species Mott insulator of boson pairs. Such a realization of exact quantum Ising model allows us to investigate both the dynamics and thermodynamics of the Ising model in ultracold atom systems. And there is no limitation on the dimension of the lattice, which means the effective quantum Ising model in any achievable lattice configurations can all be simulated. These results may give some inspirations for experimental investigation of the exact solution of three-dimensional Ising model, classical and quantum critical phenomenon, quantum simulation of a spin liquid and other interesting topics related with the Ising model in ultracold atom systems.