Enhanced sensing of optomechanically induced nonlinearity by linewidth suppression and optical bistability in cavity-waveguide systems

TL;DR

This paper demonstrates that combining linewidth suppression and optical bistability in an anti-PT symmetric cavity-waveguide system significantly enhances the sensitivity of optomechanical nonlinearity sensing, surpassing previous models.

Contribution

It introduces a novel scheme leveraging linewidth suppression and optical bistability to greatly improve sensing sensitivity in cavity-waveguide systems with anti-PT symmetry.

Findings

Sensitivity is enhanced by two orders of magnitude.

The scheme is robust against cavity decay and detuning fluctuations.

Potential for high-precision measurements in Kerr-type nonlinear systems.

Abstract

We study enhanced sensing of optomechanically induced nonlinearity (OMIN) in a cavity-waveguide coupled system. The Hamiltonian of the system is anti-PT symmetric with the two involved cavities being dissipatively coupled via the waveguide. When a weak waveguide-mediated coherent coupling is introduced, the anti-PT symmetry may break down. However, we find a strong bistable response of the cavity intensity to the OMIN near the cavity resonance, benefiting from linewidth suppression caused by the vacuum induced coherence. The joint effect of optical bistability and the linewidth suppression is inaccessible by the anti-PT symmetric system involving only dissipative coupling. Due to that, the sensitivity is greatly enhanced by two orders of magnitude compared to that for the anti-PT symmetric model. Moreover, the sensitivity shows resistances to a reasonably large cavity decay and robustness to fluctuations in the cavity-waveguide detuning. Based on the integrated optomechanical cavity-waveguide systems, the scheme can be used for sensing different physical quantities related to the single-photon coupling strength, and has potential applications in high-precision measurements with physical systems involving Kerr-type nonlinearity.