Dc atomtronic quantum interference device: Quantum superposition of persistent-current states and a parity-protected qubit

Abstract

A generalized Bose-Hubbard model in a two-mode approximation is applied to study the rotational dynamics of a direct-current atomtronic quantum interference device. Modified values of on-site interaction and pair-tunneling parameters of the Hamiltonian, derived from the small-oscillation periods of the Josephson modes, are shown to provide an excellent agreement to the Gross-Pitaevskii simulation results for the whole rotational frequency range, reaching also the critical values of imbalance and current. This amounts to a full validation of the semiclassical approximation of the modified Hamiltonian, whose quantization is employed to investigate the quantum features of the stationary states. Focusing on the frequency interval where the potential energy presents two minima, it is shown that the central frequency, at which such minima are symmetric, yields an atom number parity-protected qubit with a maximum entanglement of both persistent-current states, similar to those of superconducting circuits threaded by a half-quantumof applied flux. Such a parity protection scheme survives within a small interval around the central frequency, which sets the minimum rotational frequency precision that should be required to implement the qubit. It is found that such a maximum admissible error in the frequency determination turns out to be inversely proportional to the qubit quality factor that measures the gap between the qubit energy levels and the following levels. It is shown that the chemical potential or condensate particle number could be employed as suitable control parametersto achieve the best trade-off between such qubit characteristics.