English

Single-qubit quantum gate at an arbitrary speed

Quantum Physics 2024-12-30 v1

Abstract

Quantum information processing comprises physical processes, which obey the quantum speed limit (QSL): high speed requires strong driving. Single-qubit gates using Rabi oscillation, which is based on the rotating wave approximation (RWA), satisfy this bound in the form that the gate time TT is inversely proportional to the Rabi frequency Ω\Omega, characterizing the driving strength. However, if the gate time is comparable or shorter than the qubit period T02π/ω0T_{0} \equiv 2\pi / \omega_{0}, the RWA actually breaks down since the Rabi frequency has to be large compared to the qubit frequency ω0\omega_{0} due to the QSL, which is given as Tπ/ΩT \gtrsim \pi/\Omega. We show that it is possible to construct a universal set of single-qubit gates at this strong-coupling and ultrafast regime, by adjusting the central frequency ω\omega and the Rabi frequency Ω\Omega of the driving pulse. We observe a transition in the scaling behavior of the central frequency from the long-gate time regime (TT0T \gg T_{0}) to the short-gate time (TT0T \ll T_{0}) regime. In the former, the central frequency is nearly resonant to the qubit, i.e., ωω0\omega \simeq \omega_{0}, whereas in the latter, the central frequency is inversely proportional to the gate time, i.e., ωπ/T\omega \sim \pi/T. We identify the transition gate time at which the scaling exponent nn of the optimal central frequency ωTn\omega \sim T^{n} changes from n=0n=0 to n=1n=-1.

Keywords

Cite

@article{arxiv.2412.19561,
  title  = {Single-qubit quantum gate at an arbitrary speed},
  author = {Seongjin Ahn and Kichan Park and Daehee Cho and Mikyoung Lim and Taeyoung Choi and Andrey S. Moskalenko},
  journal= {arXiv preprint arXiv:2412.19561},
  year   = {2024}
}

Comments

11 pages, 4 figures

R2 v1 2026-06-28T20:49:46.191Z