Quantum simulation of fermionic non-Abelian lattice gauge theories in $(2+1)$D with built-in gauge protection

TL;DR

This paper proposes a novel quantum simulation approach for non-Abelian lattice gauge theories in 2+1 dimensions, ensuring gauge invariance and introducing a gauge protection scheme suitable for large-scale experimental implementation.

Contribution

It introduces a minimal model for non-Abelian LGTs with explicit gauge constraints and a new gauge protection scheme using native AELA interactions, enabling scalable digital-analog simulations.

Findings

Designed a gauge-invariant minimal model for non-Abelian LGTs

Developed a gauge protection scheme compatible with AELAs

Extended approach to scalable $U(N)$ LGT simulation with Rydberg atoms

Abstract

Recent advancements in the field of quantum simulation have significantly expanded the potential for applications, particularly in the context of lattice gauge theories (LGTs). Maintaining gauge invariance throughout a simulation remains a central challenge, especially for large-scale non-Abelian LGTs with dynamical matter, which are particularly complex in terms of engineering for experiments. Gauge-symmetry breaking is inevitable in established rishon-based schemes for alkaline-earth-like atoms (AELAs) and controlling the magnitude of its effect is an open challenge. Here, we first construct a minimal model to quantum simulate non-Abelian LGTs ensuring that the gauge constraints are met and explicitly derive their unambiguous non-Abelian nature. Second, we present a proposal for a novel gauge protection scheme using native interactions in AELAs enabling the simulation of toy models of non-Abelian $U(2)$ LGTs with dynamical fermionic matter in $(2+1)$ dimensions on large scales. Due to the simplicity of the gauge protection mechanism, based on a Zeeman shift in combination with superexchange interactions, our scheme can be naturally included in other rishon-based quantum simulation protocols. Third, we extend our approach to a fully scalable, hybrid digital-analog simulator for $U(N)$ LGTs based on Rydberg AELA with variable rishon number. The proposed general mechanism for gauge protection provides a promising path towards the long-awaited simulation of non-Abelian LGTs relevant to particle physics.