Coupling-induced universal dynamics in bilayer two-dimensional Bose gases

TL;DR

This paper investigates universal self-similar dynamics in a bilayer 2D Bose gas driven by interlayer coupling, revealing diffusion-like coarsening and vortex dynamics, advancing understanding of non-equilibrium universality.

Contribution

It demonstrates controlled interlayer coupling quench in a bilayer Bose gas and observes universal dynamics consistent with theoretical models.

Findings

Universal self-similar dynamics observed

Critical exponent matches diffusion-like coarsening

Vortex-antivortex annihilation drives the process

Abstract

The emergence of order in many-body systems and the associated self-similar dynamics governed by dynamical scaling laws is a hallmark of universality far from equilibrium. Measuring and classifying such nontrivial behavior for novel symmetry classes remains challenging. Here, we realize a well-controlled interlayer coupling quench in a tunable bilayer two-dimensional Bose gas, driving the system to an ordered phase. We observe robust self-similar dynamics and a universal critical exponent consistent with diffusion-like coarsening, driven by vortex and antivortex annihilation induced by the interlayer coupling. Our results extend the understanding of universal dynamics in many-body systems and provide a robust foundation for quantitative tests of nonequilibrium effective field theories.