Circuit-QED simulator of the Bose-Hubbard model for quantum spin dynamics

  1. Ivan V. Dudinets,
  2. Jaehee Kim,
  3. Tomás Ramos,
  4. Aleksey K. Fedorov,
  5. Vladimir I Man'ko,
  6. and Joonsuk Huh
We demonstrate an experimentally feasible circuit-QED Bose-Hubbard simulator that reproduces the complex spin dynamics of Heisenberg models. Our method relies on mapping spin-1/2 systems onto bosonic states via the polynomially expanded Holstein-Primakoff (HP) transformation. The HP transformation translates the intricate behavior of spins into a representation that is compatible with bosonic devices like those in a circuit QED setup. For comparison, we also implement the Dyson-Maleev (DM) encoding for spin-1/2 and show that, in this limit, DM and HP are equivalent. We show the equivalence of the DM and the HP transformations for spin-1/2 systems. Rigorous numerical analyses confirm the effectiveness of our HP-based protocol. Specifically, we obtain the concurrence between the spin dynamics and the behavior of microwave photons within our circuit QED-based analog simulator that is designed for the Bose-Hubbard model. By utilizing the microwave photons inherent to circuit QED devices, our framework presents an accessible, scalable avenue for probing quantum spin dynamics in an experimentally viable setting.

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