From Independent to Joint: Enhancing Quantum Phase and Correlation Factor Estimation by Squeezed Reservoir Engineering

Abstract

High-precision quantum parameter estimation is fundamental to the advancement of quantum metrology. Although reservoir engineering provides a powerful approach to improve estimation by tailoring system-environment interactions, the role of the squeezing phase and correlations arising from the sequential utilization of the same squeezed reservoir remains inadequately explored. In this work, we employ a correlated squeezed-thermal reservoir to enhance the precision of estimating the phase parameter φ and the correlation factor μ, both individually and simultaneously. We show that the squeezing phase is crucial for achieving quantum-enhanced precision, with optimal phase-matching conditions that depend strongly on μ. Specifically, we derive the near-optimal phase-matching relations aimed at maximizing the quantum Fisher information (QFI) for both φ and μ, as well as minimizing the total variance sim in joint estimation. Furthermore, we show that the joint estimation variance is dominated by Fφ, which motivates our search for the phase-matching conditions that minimize sim. Through the ratio R of variances, we demonstrate that joint estimation conserves quantum resources and maintains high precision when the squeezing phase is optimized for Fφ, despite the inherent incompatibility of the parameters. These findings provide practical insights into reservoir engineering strategies for high-precision quantum sensing and information processing.