New trends in quantum integrability: Recent experiments with ultracold atoms

TL;DR

Recent experimental advances with ultracold atoms have enabled the realization and study of exactly solvable quantum many-body systems, revealing fundamental 1D phenomena and inspiring progress in quantum physics and mathematics.

Contribution

This paper reviews recent experimental developments in quantum integrability using ultracold atoms and connects these findings with exact solutions of 1D quantum systems.

Findings

Observation of generalized hydrodynamics in 1D systems

Experimental realization of spin-charge separation

Detection of quantum holonomy and fractional exclusion statistics

Abstract

Over the past two decades quantum engineering has made significant advances in our ability to create genuine quantum many-body systems using ultracold atoms. In particular, some prototypical exactly solvable Yang-Baxter systems have been successfully realized allowing us to confront elegant and sophisticated exact solutions of these systems with their experimental counterparts. The new experimental developments show a variety of fundamental one-dimensional (1D) phenomena, ranging from the generalized hydrodynamics to dynamical fermionization, Tomonaga-Luttinger liquids, collective excitations, fractional exclusion statistics, quantum holonomy, spin-charge separation, competing orders with high spin symmetry and quantum impurity problems. This article briefly reviews these developments and provides rigorous understanding of those observed phenomena based on the exact solutions while highlighting the uniqueness of 1D quantum physics. The precision of atomic physics realizations of integrable many-body problems continues to inspire significant developments in mathematics and physics while at the same time offering the prospect to contribute to future quantum technology.