Phase-dependent optical response properties in an optomechanical system by coherently driving the mechanical resonator

TL;DR

This paper theoretically investigates how phase control of optical response in an optomechanical system with a driven mechanical resonator can lead to complex quantum interference effects and tunable amplification.

Contribution

It introduces a novel phase-dependent control scheme for optical response in an optomechanical system with coherent mechanical driving.

Findings

Probe transmission spectra depend on the total phase of applied fields.

Phase control enables tunable amplification and interference effects.

The study offers a new method for manipulating light propagation in optomechanical systems.

Abstract

We explore theoretically the optical response properties in an optomechanical system under electromagneti- cally induced transparency condition but with the mechanical resonator being driven by an additional coherent field. In this configuration, more complex quantum coherent and interference phenomena occur. In partic- ular, we find that the probe transmission spectra depend on the total phase of the applied fields. Our study also provides an efficient way to control propagation of amplification.