String breaking mechanism in a lattice Schwinger model simulator

TL;DR

This paper demonstrates the observation of string breaking in a one-dimensional lattice gauge theory using an optical lattice quantum simulator, providing experimental insights into a fundamental non-perturbative phenomenon in gauge theories.

Contribution

First experimental realization of string breaking in a lattice gauge theory using optical lattices, with controlled state preparation and adiabatic tuning to observe microscopic confined phases.

Findings

String breaking occurs under a resonance condition.

Microscopic confined phases exhibit string or broken-string states.

Optical lattices can simulate complex gauge theory phenomena.

Abstract

String breaking is a fundamental concept in gauge theories, describing the decay of a flux string connecting two charges through the production of particle-antiparticle pairs. This phenomenon is particularly important in particle physics, notably in Quantum Chromodynamics, and plays a crucial role in condensed matter physics. However, achieving a theoretical understanding of this non-perturbative effect is challenging, as conventional numerical approaches often fall short and require substantial computational resources. On the experimental side, studying these effects necessitates advanced setups, such as high-energy colliders, which makes direct observation difficult. Here, we report an experimental investigation of the string breaking mechanism in a one-dimensional U(1) lattice gauge theory using an optical lattice quantum simulator. By deterministically preparing initial states of varying lengths with fixed charges at each end, and adiabatically tuning the mass and string tension, we observed in situ microscopic confined phases that exhibit either string or brokenstring states. Further analysis reveals that string breaking occurs under a resonance condition, leading to the creation of new particle-antiparticle pairs. These findings offer compelling evidence of string breaking and provide valuable insights into the intricate dynamics of lattice gauge theories. Our work underscores the potential of optical lattices as controllable quantum simulators, enabling the exploration of complex gauge theories and their associated phenomena.