A quantum electromechanical interface for long-lived phonons
Abstract
Controlling long-lived mechanical oscillators in the quantum regime holds promises for quantum information processing. Here, we present an electromechanical system capable of operating in the GHz-frequency band in a silicon-on-insulator platform. Relying on a novel driving scheme based on an electrostatic field and high-impedance microwave cavities based on TiN superinductors, we are able to demonstrate a parametrically-enhanced electromechanical coupling of MHz, sufficient to enter the strong-coupling regime with a cooperativity of . The absence of piezoelectric materials in our platform leads to long mechanical lifetimes, finding intrinsic values up to s ( at GHz) measured at low-phonon numbers and millikelvin temperatures. Despite the strong parametric drives, we find the cavity-mechanics system in the quantum ground state by performing sideband thermometry measurements. Simultaneously achieving ground-state operation, long mechanical lifetimes, and strong coupling sets the stage for employing silicon electromechanical resonators as memory elements and transducers in hybrid quantum systems, and as a tool for probing the origins of acoustic loss in the quantum regime.
Cite
@article{arxiv.2207.10972,
title = {A quantum electromechanical interface for long-lived phonons},
author = {Alkim Bozkurt and Han Zhao and Chaitali Joshi and Henry G. LeDuc and Peter K. Day and Mohammad Mirhosseini},
journal= {arXiv preprint arXiv:2207.10972},
year = {2022}
}