Quantum Shock Waves and Population Inversion in Collisions of Ultracold Atomic Clouds

TL;DR

This study uses advanced numerical methods to analyze ultracold atomic cloud collisions, revealing quantum shock waves, population inversion, and the limits of hydrodynamic models in describing out-of-equilibrium quantum dynamics.

Contribution

It demonstrates the formation of quantum shock waves and population inversion during cloud collisions, highlighting the breakdown of hydrodynamics and advancing understanding of quantum many-body out-of-equilibrium behavior.

Findings

Hydrodynamics describes long-term breathing modes but fails during collisions.

Quantum shock waves form during cloud collisions.

Population inversion with negative effective temperature occurs at shock formation.

Abstract

Using Time-Dependent Density Matrix Renormalization Group (TDMRG) we study the collision of one-dimensional atomic clouds confined in a harmonic trap and evolving with the Lieb-Liniger Hamiltonian. It is observed that the motion is essentially periodic with the clouds bouncing elastically, at least on the time scale of the first few oscillations that can be resolved with high accuracy. This is in agreement with the results of the "quantum Newton cradle" experiment of Kinoshita et al. [Nature 440, 900 (2006)]. We compare the results for the density profile against a hydrodynamic description, or generalized nonlinear Schr\"odinger equation, with the pressure term taken from the Bethe Ansatz solution of the Lieb-Liniger model. We find that hydrodynamics can describe the breathing mode of a harmonically trapped cloud for arbitrary long times while it breaks down almost immediately for the collision of two clouds due to the formation of shock waves (gradient catastrophe). In the case of the clouds' collision TDMRG alone allows to extract the oscillation period which is found to be measurably different from the breathing mode period. Concomitantly with the shock waves formation we observe a local energy distribution typical of population inversion, i.e., an effective negative temperature. Our results are an important step towards understanding the hydrodynamics of quantum many-body systems out of equilibrium and the role of integrability in their dynamics.