Effects of classical stochastic webs on the quantum dynamics of cold atomic gases in a moving optical lattice

TL;DR

This paper explores how classical stochastic webs influence quantum dynamics in cold atomic gases within a moving optical lattice, revealing controllable pathways that affect energy transfer and are enhanced by atomic interactions.

Contribution

It introduces a novel system leveraging phase space pathways to control atom-lattice interactions and demonstrates their impact on Bose-Einstein condensate dynamics.

Findings

Pathways form web-like patterns controllable by lattice parameters.

Control of BEC kinetic energy via pathway topology.

Atomic interactions amplify atom-lattice coupling effects.

Abstract

We introduce and investigate a system that uses temporal resonance-induced phase space pathways to create strong coupling between an atomic Bose-Einstein condensate and a traveling optical lattice potential. We show that these pathways thread both the classical and quantum phase space of the atom cloud, even when the optical lattice potential is arbitrarily weak. The topology of the pathways, which form web-like patterns, can by controled by changing the amplitude and period of the optical lattice. In turn, this control can be used to increase and limit the BEC's center-of-mass kinetic energy to pre-specified values. Surprisingly, the strength of the atom-lattice interaction and resulting BEC heating of the center-of-mass motion is enhanced by the repulsive inter-atomic interactions.