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Proposals for experimentally realizing (mostly) quantum-autonomous gates

Quantum Physics 2025-11-06 v2

Abstract

Autonomous quantum machines (AQMs) execute tasks without requiring time-dependent external control. Motivations for AQMs include the restrictions imposed by classical control on quantum machines' coherence times and geometries. Most AQM work is theoretical and abstract; yet an experiment recently demonstrated AQMs' usefulness in qubit reset, crucial to quantum computing. To further reduce quantum computing's classical control, we propose realizations of (fully and partially) quantum-autonomous gates on three platforms: Rydberg atoms, trapped ions, and superconducting qubits. First, we show that a Rydberg-blockade interaction or an ultrafast transition can quantum-autonomously effect entangling gates on Rydberg atoms. One can perform ZZ or entangling gates on trapped ions mostly quantum-autonomously, by sculpting a linear Paul trap or leveraging a ring trap. Passive lasers control these gates, as well as the Rydberg-atom gates, quantum-autonomously. Finally, circuit quantum electrodynamics can enable quantum-autonomous ZZ and XYXY gates on superconducting qubits. The gates can serve as building blocks for (fully or partially) quantum-autonomous circuits, which may reduce classical-control burdens.

Keywords

Cite

@article{arxiv.2510.07372,
  title  = {Proposals for experimentally realizing (mostly) quantum-autonomous gates},
  author = {José Antonio Marín Guzmán and Yu-Xin Wang and Tom Manovitz and Paul Erker and Norbert M. Linke and Simone Gasparinetti and Nicole Yunger Halpern},
  journal= {arXiv preprint arXiv:2510.07372},
  year   = {2025}
}

Comments

11.5 pages (8 figures) + appendices (7 pages). Trapped-ion section updated

R2 v1 2026-07-01T06:24:47.931Z