Quantum Simulation with Fluxonium Qutrit Arrays

TL;DR

This paper explores the use of fluxonium superconducting circuits as tunable qutrits for quantum simulation, revealing diverse operational regimes and interactions, and proposing experiments to study strongly correlated quantum matter.

Contribution

It introduces fluxonium qutrit arrays as a versatile platform for simulating exotic quantum phases beyond traditional models.

Findings

Identification of four operational regimes based on excitation nature

Highly tunable interactions including correlated hopping and non-local terms

Potential to simulate lattice gauge theories and topological states

Abstract

Fluxonium superconducting circuits were originally proposed to realize highly coherent qubits. In this work, we explore how these circuits can be used to implement and harness qutrits, by tuning their energy levels and matrix elements via an external flux bias. In particular, we investigate the distinctive features of arrays of fluxonium qutrits, and their potential for the quantum simulation of exotic quantum matter. We identify four different operational regimes, classified according to the plasmon-like versus fluxon-like nature of the qutrit excitations. Highly tunable on-site interactions are complemented by correlated single-particle hopping, pair hopping and non-local interactions, which naturally emerge and have different weights in the four regimes. Dispersive corrections and decoherence are also analyzed. We investigate the rich ground-state phase diagram of qutrit arrays and propose practical dynamical experiments to probe the different regimes. Altogether, fluxonium qutrit arrays emerge as a versatile and experimentally accessible platform to explore strongly correlated bosonic matter beyond the Bose-Hubbard paradigm, and with a potential toward simulating lattice gauge theories and non-Abelian topological states.