Chiral and bond-ordered phases in a triangular-ladder superconducting-qubit quantum simulator

TL;DR

This paper demonstrates how superconducting qubits can simulate complex Bose-Hubbard models on a triangular ladder, revealing chiral and bond-ordered phases through tunable parameters and measurements of quantum correlations.

Contribution

It introduces a superconducting-qubit platform for simulating frustrated Bose-Hubbard systems and characterizes novel quantum phases with tunable synthetic magnetic flux.

Findings

Observation of signatures of chiral superfluids.

Detection of bond-ordered insulators.

Identification of Meissner superfluid phases.

Abstract

Many-body systems with strong interactions often exhibit macroscopic behavior markedly absent in single-particle or noninteracting limits. Such emergent phenomena are well exemplified in lattice Hubbard models, where the interplay between interactions, geometric frustration, and magnetic flux gives rise to rich physics. Superconducting qubits naturally enable analog quantum simulation of Bose-Hubbard models, while offering tunable parameters, site-resolved control, and rapid experimental repetition rates. Here, we study a superconducting-qubit device that realizes the Bose-Hubbard model on a triangular-ladder lattice. By tuning the magnitude and sign of couplings, we engineer a synthetic magnetic flux to characterize the resulting half-filling ground state for various parameter regimes. We measure observables analogous to current-current correlators and bond kinetic energies, finding signatures consistent with chiral superfluids, Meissner superfluids, and bond-ordered insulators. Our results establish superconducting circuits as a platform for robustly probing quantum phases of matter in frustrated Bose-Hubbard systems, even in strongly correlated and gapless regimes.