Decoherence of surface phonons in a quantum acoustic system

TL;DR

This paper investigates the decoherence mechanisms in surface acoustic wave resonators coupled to superconducting qubits, providing experimental measurements and modeling insights crucial for advancing quantum acoustic technologies.

Contribution

It presents the first detailed experimental characterization of phononic decoherence rates in a strongly coupled SAW-resonator and qubit system, with analysis of sources and implications for quantum device engineering.

Findings

Measured phononic energy decay rate of 480 kHz

Observed pure dephasing rate of 180 kHz

Demonstrated the importance of open quantum system modeling

Abstract

Phononic resonators are becoming increasingly important in quantum information science, both for applications in quantum computing, communication and sensing, as well as in experiments investigating fundamental physics. Here, we study the decoherence of phonons confined in a surface acoustic wave (SAW) resonator strongly coupled ($g/2\pi\approx 9$ MHz) to a superconducting transmon qubit. By comparing experimental data with numerical solutions to the Markovian master equation, we report a surface phononic energy decay rate of $\kappa_1/2\pi=480$ kHz and a pure dephasing rate of $\kappa_{\phi}/2\pi=180$ kHz. These rates are in good agreement with the level of decoherence we extract from qubit-assisted spectroscopic measurements of the SAW resonator. We additionally find that the timescales over which coherent driven dynamics and decoherence occur are comparable, highlighting the need to model the composite device as an open quantum system. We discuss possible sources of decoherence in SAW-based quantum acoustic devices and the application of these devices in future quantum acoustic dissipation engineering experiments. The decoherence characterization techniques we employ are broadly applicable for investigating and benchmarking the effects of loss and dephasing on mechanical resonators in the quantum regime.