English

Nonlinear Coupling between Motional Modes in Trapped Ion Quantum Processors

Quantum Physics 2025-11-20 v2

Abstract

Trapped-ion crystals are a leading platform for quantum information science, but achieving the high-fidelity entangling gates required for fault-tolerant quantum computing becomes harder as system size increases. As systems scale, spectral crowding makes low-order nonlinear resonances between collective motional modes increasingly common and can limit gate performance, especially in monolithic or global-mode architectures. We develop a general model to identify and simulate nonlinear motional-mode coupling (NoMoCou) arising from third-order Coulomb terms and quantify its impact on the Molmer-Sorensen gate across linear chains and 2D crystals in rf and Penning traps. We delineate the regimes where NoMoCou dominates the error budget and provide design rules: detune operating points from low-order resonances, tune trap anisotropy to reshape spectra, and shape gate waveforms.

Keywords

Cite

@article{arxiv.2510.07590,
  title  = {Nonlinear Coupling between Motional Modes in Trapped Ion Quantum Processors},
  author = {Wes Johnson and Brandon Ruzic},
  journal= {arXiv preprint arXiv:2510.07590},
  year   = {2025}
}

Comments

31 pages, 16 figures. Revised v2: removed correspondence appendix; added acknowledgements; added robust-gate refs (Hayes 2012; Leung 2018; Kang 2021; Ruzic 2024); clarified two-ion MS-gate error model (Sutherland 2022); fixed typos

R2 v1 2026-07-01T06:25:23.180Z