Feedback cooled Bose-Einstein condensation: near and far from equilibrium

TL;DR

This paper demonstrates feedback cooling protocols for Bose-Einstein condensates that effectively reduce energy and entropy, enabling control of quantum states in 1D and 2D systems, including far-from-equilibrium states.

Contribution

It introduces the first feedback cooling protocols in 2D and significantly improves cooling efficiency in 1D BECs using momentum-dependent feedback.

Findings

Feedback protocols effectively cool 1D and 2D BECs.

Optimal protocol reduces 1D BEC energy by over 100 times.

Quench cooling produces far-from-equilibrium states with quantized supercurrents.

Abstract

Continuously measured interacting quantum systems almost invariably heat, causing loss of quantum coherence. Here, we study Bose-Einstein condensates (BECs) subject to repeated weak measurement of the atomic density and describe several protocols for generating a feedback signal designed to remove excitations created by measurement backaction. We use a stochastic Gross-Pitaevskii equation to model the system dynamics and find that a feedback protocol utilizing momentum dependant gain and filtering can effectively cool both 1D and 2D systems. The performance of these protocols is quantified in terms of the steady state energy, entropy, and condensed fraction. These are the first feedback cooling protocols demonstrated in 2D, and in 1D our optimal protocol reduces the equilibrium energy by more than a factor of 100 as compared with a previous cooling protocol developed using the same methodology. We also use this protocol to quench-cool 1D BECs from non-condensed highly excited states and find that they rapidly condense into a far from equilibrium state with energy orders of magnitude higher than the equilibrium ground state energy for that condensate fraction. We explain this in terms of the near-integrability of our 1D system, whereby efficiently cooled low momentum modes are effectively decoupled from the energetic `reservoir' of the higher momentum modes. We observe that the quench-cooled condensed states can have non-zero integer winding numbers described by quantized supercurrents.