Litcius/Paper detail

Homodyne coherent quantum noise cancellation in a hybrid optomechanical force sensor

Hossein Allahverdi, Ali Motazedifard, A. Dalafi, David Vitali, M. H. Naderi

2022Physical review. A/Physical review, A24 citationsDOIOpen Access PDF

Abstract

In this paper we propose an experimentally viable scheme to enhance the sensitivity of force detection in a hybrid optomechanical setup assisted by squeezed vacuum injection, beyond the standard quantum limit (SQL). The scheme is based on a combination of the coherent quantum noise cancellation (CQNC) strategy with a variational homodyne detection of the cavity output spectrum in which the phase of the local oscillator is optimized. In CQNC, realizing a negative-mass oscillator in the system leads to exact cancellation of the backaction noise from the mechanics due to destructive quantum interference. Squeezed vacuum injection enhances this cancellation and allows sub-SQL sensitivity to be reached in a wide frequency band and at much lower input laser powers. We show here that the adoption of variational homodyne readout enables us to enhance this noise cancellation up to $40\phantom{\rule{3.33333pt}{0ex}}\mathrm{dB}$ compared to the standard case of detection of the optical output phase quadrature, leading to a remarkable force sensitivity of the order of ${10}^{\ensuremath{-}19}\phantom{\rule{0.28em}{0ex}}\mathrm{N}/\sqrt{\mathrm{Hz}}$, about $70%$ enhancement compared to the standard case. Moreover, we show that at nonzero cavity detuning, the signal response can be amplified at a level three to five times larger than that in the standard case without variational homodyne readout, improving the signal-to-noise ratio. Finally, the variational readout CQNC developed in this paper may be applied to other optomechanical-like platforms such as levitated systems and multimode optomechanical arrays or crystals as well as Josephson-based optomechanical systems.

Topics & Concepts

Homodyne detectionPhysicsQuantum limitDirect-conversion receiverSensitivity (control systems)Noise (video)Quantum noiseQuantum mechanicsSqueezed coherent statePhase noiseQuantumLocal oscillatorOpticsCoherent statesElectronic engineeringEngineeringComputer scienceImage (mathematics)Artificial intelligenceMechanical and Optical ResonatorsAdvanced MEMS and NEMS TechnologiesForce Microscopy Techniques and Applications