English

A mechanical quantum memory for microwave photons

Quantum Physics 2024-12-12 v1

Abstract

Long-lived mechanical oscillators are actively pursued as critical resources for quantum storage, sensing, and transduction. However, achieving deterministic quantum control while limiting mechanical dissipation remains a persistent challenge. Here, we demonstrate strong coupling between a transmon superconducting qubit and an ultra-long-lived nanomechanical oscillator (T125 msT_\text{1} \approx 25 \text{ ms} at 5 GHz, Q0.8×109Q \approx 0.8 \times 10^9) by leveraging the low acoustic loss in silicon and phononic bandgap engineering. The qubit-oscillator system achieves large cooperativity (CT11.5×105C_{T_1}\approx 1.5\times10^5, CT2150C_{T_2}\approx 150), enabling the generation of non-classical states and the investigation of mechanisms underlying mechanical decoherence. We show that dynamical decoupling\unicodex2014\unicode{x2014}implemented through the qubit\unicodex2014\unicode{x2014}can mitigate decoherence, leading to a mechanical coherence time of T21 msT_2\approx 1 \text{ ms}. These findings extend the exceptional storage capabilities of mechanical oscillators to the quantum regime, putting them forward as compact bosonic elements for future applications in quantum computing and metrology.

Keywords

Cite

@article{arxiv.2412.08006,
  title  = {A mechanical quantum memory for microwave photons},
  author = {Alkım B. Bozkurt and Omid Golami and Yue Yu and Hao Tian and Mohammad Mirhosseini},
  journal= {arXiv preprint arXiv:2412.08006},
  year   = {2024}
}

Comments

30 pages, 21 figures

R2 v1 2026-06-28T20:30:20.049Z