Adiabatic passage in photon-echo quantum memories

TL;DR

This paper demonstrates that using frequency-chirped adiabatic passage pulses in photon-echo quantum memories effectively rephases atomic coherences in optically thick media, leading to high-efficiency, low-noise quantum storage.

Contribution

It introduces a novel protocol employing chirped adiabatic pulses for coherence rephasing, improving fidelity and noise performance over traditional $$-pulse schemes.

Findings

Achieves near-unit efficiency in secondary echo emission.

Reduces noise from spontaneous emission.

Enhances multi-channel quantum memory capabilities.

Abstract

Photon-echo based quantum memories use inhomogeneously broadened, optically thick ensembles of absorbers to store a weak optical signal and employ various protocols to rephase the atomic coherences for information retrieval. We study the application of two consecutive, frequency-chirped control pulses for coherence rephasing in an ensemble with a 'natural' inhomogeneous broadening. Although propagation effects distort the two control pulses differently, chirped pulses that drive adiabatic passage can rephase atomic coherences in an optically thick storage medium. Combined with spatial phase mismatching techniques to prevent primary echo emission, coherences can be rephased around the ground state to achieve secondary echo emission with close to unit efficiency. Potential advantages over similar schemes working with $\pi$-pulses include greater potential signal fidelity, reduced noise due to spontaneous emission and better capability for the storage of multiple memory channels.