Generating multipartite entangled states of qubits distributed in different cavities

TL;DR

This paper proposes a simplified method to generate multipartite entangled states of qubits distributed across different cavities, reducing decoherence and engineering complexity, with a feasible implementation in circuit QED systems.

Contribution

It introduces a novel, efficient protocol for creating $W$-class entangled states in distributed cavities without cavity photon excitation or classical pulses.

Findings

High-fidelity $W$ state generation demonstrated in circuit QED simulations.

Method reduces decoherence by avoiding cavity photon excitation.

Applicable to various qubit types beyond superconducting circuits.

Abstract

Cavity-based large-scale quantum information processing (QIP) needs a large number of qubits and placing all of them in a single cavity quickly runs into many fundamental and practical problems such as the increase of cavity decay rate and decrease of qubit-cavity coupling strength. Therefore, future QIP most likely will require quantum networks consisting of a large number of cavities, each hosting and coupled to multiple qubits. In this work, we propose a way to prepare a $W$-class entangled state of spatially-separated multiple qubits in different cavities, which are connected to a coupler qubit. Because no cavity photon is excited, decoherence caused by the cavity decay is greatly suppressed during the entanglement preparation. This proposal needs only one coupler qubit and one operational step, and does not require using a classical pulse, so that the engineering complexity is much reduced and the operation is greatly simplified. As an example of the experimental implementation, we further give a numerical analysis, which shows that high-fidelity generation of the $W$ state using three superconducting phase qubits each embedded in a one-dimensional transmission line resonator is feasible within the present circuit QED technique. The proposal is quite general and can be applied to accomplish the same task with other types of qubits such as superconducting flux qubits, charge qubits, quantum dots, nitrogen-vacancy centers and atoms.