Chiral-cat-state generation via the Sagnac-Fizeau effect

TL;DR

This paper proposes a method to generate chiral cat states in a spinning resonator using the Sagnac-Fizeau effect, enabling controlled quantum state creation with potential applications in nonreciprocal photonics.

Contribution

It introduces a novel approach for chiral cat-state generation leveraging the Sagnac-Fizeau effect in a spinning resonator with dispersively coupled atoms.

Findings

Successful generation of chiral cat states in CW mode and coherent states in CCW mode.

Analysis of quantum coherence via Wigner functions.

Investigation of dissipation effects on state fidelity.

Abstract

Chiral quantum state generation is an interesting topic in quantum physics and quantum information science. Here we propose an approach for generating chiral cat states in a spinning resonator supporting both the clockwise (CW) and counterclockwise (CCW) traveling modes, which are dispersively coupled to a two-level atom. The physical mechanism for the chiral-cat-state generation is based on the Sagnac-Fizeau effect. Concretely, when the resonator is rotating, the CW and CCW modes have different frequency detuning with respect to the atomic transition frequency and hence the atomic-state-dependent rotating angular velocities for the CW and CCW modes in phase space are different. This mode-dependent evolution leads to a chirality mechanism in the state generation. Based on the mode-dependent conditional rotation evolution and atomic projection measurement at proper time, we achieve the separate generation of cat states in the CW mode and coherent states in the CCW mode. We also investigate quantum coherence properties of the generated states by examining their Wigner functions. In addition, the influence of the system dissipations on the state generation in the open-system case is investigated. Our work will provide some insights into the development of chiral optical devices and nonreciprocal photonics.