Observation of Universal Expansion Anisotropy from Cold Atoms to Hot Quark-Gluon Plasma

TL;DR

This study reveals a universal scaling law of expansion anisotropy across vastly different physical systems, from cold atomic gases to quark-gluon plasma, based on the number of collisions per particle.

Contribution

It demonstrates for the first time a universal scaling of expansion anisotropy between cold atom and heavy-ion systems as a function of collision number.

Findings

Expansion anisotropy develops quickly at low interaction strength.

Universal power-law scaling of anisotropy with collision number.

No saturation observed in isotropy within the studied range.

Abstract

Azimuthal anisotropy has been ubiquitously observed in high-energy proton-proton, proton-nucleus, and nucleus-nucleus (heavy-ion) collisions, shaking the early belief that those anisotropies require an intense phase of multiple interactions between the created particles. This work reports a study of anisotropic expansion of cold $^{6}$Li Fermi gases, initially trapped in an anisotropic potential, as a function of the interaction strength that can be readily tuned by an external magnetic field. It is found that the expansion anisotropy builds up quickly at small interaction strength, without the need of a large amount of interactions. An unexpected and quantitative universal scaling of the expansion anisotropy is observed for the first time between cold atom and heavy-ion systems as a function of the number of collisions per particle or opacity ($n_{\rm coll}$), despite their vast differences in scale and physics. The expansion isotropy in both the cold atom gases and heavy-ion collisions increases smoothly and shows no sign of saturation in the observed opacity range, with an approximate power-law dependence of $\sqrt{n_{\rm coll}}$, characteristic of random walks. This universality potentially unifies a variety of vastly different physical systems, from weakly interacting dilute gases to the strongly interacting quark-gluon plasma of the early universe.