English

Fast single-qubit gates for continuous dynamically decoupled systems

Quantum Physics 2024-12-17 v1

Abstract

Environmental noise that couples longitudinally to a quantum system dephases that system and can limit its coherence lifetime. Performance using quantum superposition in clocks, information processors, communication networks, and sensors depends on careful state and external field selection to lower sensitivity to longitudinal noise. In many cases time varying external control fields--such as the Hahn echo sequence originally developed for nuclear magnetic resonance applications--can passively correct for longitudinal errors. There also exist continuous versions of passive correction called continuous dynamical decoupling (CDD), or spin-locking depending on context. However, treating quantum systems under CDD as qubits has not been well explored. Here, we develop universal single-qubit gates that are ``fast'' relative to perturbative Rabi gates and applicable to any CDD qubit architecture. We demonstrate single-qubit gates with fidelity F=0.9947(1)\mathcal{F}=0.9947(1) on a frequency tunable CDD transmon superconducting circuit operated where it is strongly sensitive to longitudinal noise, thus establishing this technique as a potentially useful tool for operating qubits in applications requiring high fidelity under non-ideal conditions.

Keywords

Cite

@article{arxiv.2412.11821,
  title  = {Fast single-qubit gates for continuous dynamically decoupled systems},
  author = {Michael Senatore and Daniel L. Campbell and James A. Williams and Matthew D. LaHaye},
  journal= {arXiv preprint arXiv:2412.11821},
  year   = {2024}
}

Comments

10 pages, 7 figures

R2 v1 2026-06-28T20:37:07.166Z