Designer Spatial Control of Interactions in Ultracold Gases

TL;DR

This paper demonstrates precise spatial control of interactions in ultracold $^6$Li gases using optical methods, enabling tailored quantum phases and accurate modeling of interaction profiles.

Contribution

It introduces a novel optical technique to spatially engineer interactions in ultracold gases, validated by experimental measurements and theoretical modeling.

Findings

Successful creation of spatially varying interaction regions using laser beams.

Radio-frequency spectroscopy confirms the imprinted interaction profiles.

Optical control achieves a tuning range comparable to magnetic methods.

Abstract

Designer optical control of interactions in ultracold atomic gases has wide application, from creating new quantum phases to modeling the physics of black holes. We demonstrate spatial control of interactions in a two-component cloud of $^6$Li fermions, using electromagnetically induced transparency (EIT) to create a "sandwich" of resonantly and weakly interacting regions. Interaction designs are imprinted on the trapped cloud by two laser beams and manipulated with just MHz changes in the frequency of one beam. We employ radio-frequency spectroscopy to measure the imprinted 1D spatial profiles of the local mean-field interactions and to demonstrate that the tuning range of the scattering length is the same for both optical and magnetic control. All of the data are in excellent agreement with our continuum-dressed state theoretical model of optical control, which includes both the spatial and momentum dependence of the interactions.