Ground state bistability of cold atoms in a cavity

TL;DR

This paper demonstrates optical bistability between two hyperfine ground states of cold atoms in a cavity, driven by cavity-assisted pumping, with implications for quantum information storage.

Contribution

It reports a novel form of ground state bistability in cold atoms, driven by cavity-assisted transitions, distinct from saturation-based bistability.

Findings

Bistability depends on laser intensities and cavity parameters.

Hysteresis observed confirms first-order phase transition.

Phase diagram matches semiclassical mean-field predictions.

Abstract

We experimentally demonstrate an optical bistability between two hyperfine atomic ground states, using a single mode of an optical resonator in the collective strong coupling regime. Whereas in the familiar case, the bistable region is created through atomic saturation, we report an effect between states of high quantum purity, which is essential for future information storage. The nonlinearity of the transitions arise from cavity-assisted pumping between ground states of cold, trapped atoms and the stability depends on the intensity of two driving lasers. We interpret the phenomenon in terms of the recent paradigm of first-order, driven-dissipative phase transitions, where the transmitted and driving fields are understood as the order and control parameters, respectively. The saturation-induced bistability is recovered for infinite drive in one of the controls. The order of the transition is confirmed experimentally by hysteresis in the order parameter when either of the two control parameters is swept repeatedly across the bistability region and the underlying phase diagram is predicted in line with semiclassical mean-field theory.