Optomechanical light storage in a silica microresonator

TL;DR

This paper demonstrates coherent optical pulse storage in a silica microresonator via optomechanical interactions, showing phase-preserving retrieval and linking light storage with optomechanically induced transparency.

Contribution

It expands previous work by experimentally confirming the coherence of light storage and exploring the influence of optomechanical coupling on pulse retrieval.

Findings

Heterodyne beating confirms phase coherence of stored and retrieved pulses.

Storage efficiency increases with optomechanical coupling rate.

Light storage and optomechanically induced transparency are closely related phenomena.

Abstract

Coherent inter-conversion between an optical and a mechanical excitation in an optomechanical resonator can be used for the storage of an optical pulse as an excitation in a mechanical oscillator. This optomechanical light storage is enabled by external writing and readout pulses at one mechanical frequency below the optical resonance. In this paper, we expand an earlier experimental study [Phys. Rev. Lett. 107, 133601 (2011)] on storing an optical pulse as a radial breathing mode in a silica microsphere. We show that the heterodyne beating between a readout pulse and the corresponding retrieved pulse features a periodic oscillation with a well-defined phase and with the beating period given by the mechanical frequency, demonstrating directly the coherent nature of the light storage process. The coherent inter-conversion accelerates with increasing optomechanical coupling rates, providing an effective mechanism for tailoring the temporal profile of the retrieved pulse. Experimental studies on both light storage and optomechanically induced transparency under nearly the same conditions also illustrate the connections between these two closely-related processes.