Generating entanglement of two acoustic modes by driving the qubit in circuit quantum acoustodynamics system

TL;DR

This paper proposes a method to generate entanglement between two acoustic modes in a circuit quantum acoustodynamics system by using a driven qubit to induce indirect interactions, demonstrating robustness and feasibility with current technology.

Contribution

It introduces a novel scheme for entangling acoustic modes via a driven qubit, with detailed analysis of parameter conditions and robustness against noise.

Findings

Entanglement can be generated through parametric-amplification-type interaction.

The scheme is feasible with current experimental parameters.

The entanglement is robust against dissipation and environmental noise.

Abstract

We propose how to generate the entanglement of two long-lived phonon modes in a circuit quantum acoustodynamics system, which consists of a multi-mode high-frequency bulk acoustic wave resonator and a transmon-type superconducting qubit. Two acoustic modes couple to the qubit through piezoelectric interaction, and the qubit is driven by a microwave field. Under the condition of far detuning between the qubit and acoustic modes, the qubit can be eliminated adiabatically, and thus establishing the indirect interaction between the two acoustic modes. We demonstrate that such the indirect interaction can be the parametric-amplification-type interaction by appropriately choosing the drive frequency and strength, so the entanglement between acoustic modes can be created by the direct unitary evolution. We numerically analyze the parameter conditions for generating the entanglement in detail and evaluate the influence of system dissipations and noise. The results show that the scheme can be realized using currently available parameters and has strong robustness against the dissipations and environmental temperature. This work may provide efficient resource for the quantum information processing based on the phononic systems.