Metrological Sensitivity beyond Gaussian Limits with Cubic Phase States

TL;DR

This paper demonstrates that cubic phase states enable quantum metrology to surpass Gaussian limits in phase sensing, with robustness against noise and achievable with moderate squeezing.

Contribution

It introduces the use of cubic phase states for quantum metrology, showing they outperform Gaussian states and identifying optimal measurement strategies.

Findings

Cubic phase states surpass Gaussian states in phase sensitivity at the same photon number.

Optimal measurement strategies are identified for these non-Gaussian states.

Robustness of the advantage against loss and detection noise is demonstrated.

Abstract

Cubic phase states provide the essential non-Gaussian resource for continuous-variable quantum computing. We show that they also offer significant potential for quantum metrology, surpassing the phase-sensing sensitivity of all Gaussian states at equal average photon number. Optimal sensitivity requires only moderate initial squeezing, and the non-Gaussian advantage remains robust against loss and detection noise. We identify optimal measurement strategies and show that several experimentally relevant preparation schemes surpass Gaussian limits, in some cases reaching the sensitivity of cubic phase states. Our results establish cubic phase states as a promising resource for quantum-enhanced precision measurements beyond Gaussian limits.