Two-time correlators for propagating squeezed microwave in transients

TL;DR

This paper develops a semiclassical method to calculate two-time correlators of propagating squeezed microwave fields in transient regimes, providing insights relevant for quantum measurements and applicable to optical systems.

Contribution

It introduces a new technique for computing two-time correlators in transient regimes of squeezed fields, extending previous steady-state analyses.

Findings

Correlators depend on four parameters in the transient regime.

The formalism applies to both microwave and optical systems.

Results are experimentally verifiable.

Abstract

We analyze two-time correlators as the most natural characteristic of a propagating quadrature-squeezed field in the transient regime. The considered system is a parametrically driven resonator with a time-dependent drive. Using a semiclassical approach derived from the input-output theory, we develop a technique for calculation of the two-time correlators, which are directly related to fluctuations of the measured integrated signal. While in the steady state the correlators are determined by three parameters (as for the phase-space ellipse describing a squeezed state), four parameters are necessary in the transient regime. The formalism can be generalized to weakly nonlinear resonators with additional coherent drive. We focus on squeezed microwave fields relevant to the measurement of superconducting qubits; however, our formalism is also applicable to optical systems. The results can be readily verified experimentally.