Creation, storage and retrieval of an optomechanical cat state

TL;DR

This paper proposes a method for creating, storing, and retrieving optomechanical Schrödinger cat states, using numerical simulations and analytical models to analyze decoherence effects and validate the quantum memory protocol.

Contribution

It introduces a comprehensive quantum memory protocol for optomechanical cat states, combining numerical and analytical methods to account for decoherence and environmental effects.

Findings

Numerical simulations demonstrate the feasibility of storing and retrieving optomechanical cat states.

Analytical bounds on decoherence timescales are consistent with numerical results.

The protocol effectively preserves non-classical signatures like Wigner negativity under certain conditions.

Abstract

We analyze a method for the creation, storage and retrieval of optomechanical Schrodinger cat states, in which there is a quantum superposition of two distinct macroscopic states of a mechanical oscillator. In the proposal, an optical cat state is first prepared in an optical cavity, then transferred to the mechanical mode, where it is stored and later retrieved using control fields. We carry out numerical simulations for the quantum memory protocol for optomechanical cat states using the positive-P phase space representation. This has a compact, positive representation for a cat state, thus allowing a probabilistic simulation of this highly non-classical quantum system. To verify the effectiveness of the cat-state quantum memory, we consider several cat-state signatures and show how they can be computed. We also investigate the effects of decoherence on a cat state by solving the standard master equation for a simplified model analytically, allowing us to compare with the numerical results. Focusing on the negativity of the Wigner function as a signature of the cat state, we evaluate analytically an upper bound on the time taken for the negativity to vanish, for a given temperature of the environment of the mechanical oscillator. We show consistency with the numerical methods. These provide exact solutions, allowing a full treatment of decoherence in an experiment that involves creating, storing and retrieving mechanical cat states using temporally mode-matched input and output pulses. Our analysis treats the internal optical and mechanical modes of an optomechanical oscillator, and the complete set of input and output field modes which become entangled with the internal modes. The model includes decoherence due to thermal effects in the mechanical reservoirs, as well as optical and mechanical losses.