Implementation of Traveling Odd Schrödinger Cat States in Circuit-QED

Jaewoo Joo,Su-Yong Lee,Jaewan Kim

doi:10.3390/photonics3040057

Abstract

We propose a realistic scheme of generating a traveling odd Schrödinger cat state and a generalized entangled coherent state in circuit quantum electrodynamics (circuit-QED). A squeezed vacuum state is used as the initial resource of nonclassical states, which can be created through a Josephson traveling-wave parametric amplifier, and travels through a transmission line. Because a single-photon subtraction from the squeezed vacuum gives an odd Schrödinger cat state with very high fidelity, we consider a specific circuit-QED setup consisting of the Josephson amplifier creating the traveling resource in a line, a beam-splitter coupling two transmission lines, and a single photon detector located at the end of the other line. When a single microwave photon is detected by measuring the excited state of a superconducting qubit in the detector, a heralded cat state is generated with high fidelity in the opposite line. For example, we show that the high fidelity of the outcome with the ideal cat state can be achieved with appropriate squeezing parameters theoretically. As its extended setup, we suggest that generalized entangled coherent states can be also built probabilistically and that they are useful for microwave quantum information processing for error-correctable qudits in circuit-QED.

Highlights

Since the thought-experiment of Schrödinger cat states (SCSs) was proposed as an example of macroscopic superposed states in 1935 [1], the implementation of this quantum coherence has been investigated in various physical systems
Using a traveling photon resource from Josephson traveling-wave parametric amplifier (JTWPA)/Josephson parametric amplifier (JPA), many interesting experiments have been performed in circuit-QED beyond conventional experiments in quantum optics [46,47,48] and this technical development allows us to investigate traveling microwave qubits through transmission lines corresponding to a photonic quantum information (QI) processing in quantum optics [49]
If the detector of a single microwave photon is located in the other line, the event of the photon measurement reveals the single-photon subtraction from the SVS and the output state has very high fidelity compared with the traveling odd SCS

Summary

Introduction

Since the thought-experiment of Schrödinger cat states (SCSs) was proposed as an example of macroscopic superposed states in 1935 [1], the implementation of this quantum coherence has been investigated in various physical systems. Using a traveling photon resource from JTWPA/JPA, many interesting experiments have been performed in circuit-QED beyond conventional experiments in quantum optics [46,47,48] and this technical development allows us to investigate traveling microwave qubits through transmission lines corresponding to a photonic QI processing in quantum optics [49]. If the detector of a single microwave photon is located in the other line, the event of the photon measurement reveals the single-photon subtraction from the SVS and the output state has very high fidelity compared with the traveling odd SCS. Once a microwave photon is detected using a superconducting qubit inside a cavity, the state becomes a single-photon subtracted SVS in the other line approximately. This can be verified by quadrature measurements

Photon-Subtraction from an SVS

Protocol

Single-Photon Detection with a BS T

Traveling Qudit ECS

Conclusions and Remarks