Rydberg-atom-based scheme of nonadiabatic geometric quantum computation
P. Z. Zhao, Xiao-Dan Cui, G. F. Xu, Erik Sj\"oqvist, D. M. Tong
TL;DR
This paper proposes a scheme for nonadiabatic geometric quantum computation using Rydberg atoms, leveraging their long coherence times and Rydberg-mediated interactions to achieve fast, robust quantum gates.
Contribution
It introduces a novel scheme combining nonadiabatic geometric gates with Rydberg atoms for quantum computation.
Findings
Scheme demonstrates potential for robust quantum gates
Utilizes Rydberg atoms' long coherence times
Facilitates implementation of two-qubit gates
Abstract
Nonadiabatic geometric quantum computation provides a means to perform fast and robust quantum gates. It has been implemented in various physical systems, such as trapped ions, nuclear magnetic resonance and superconducting circuits. Another system being adequate for implementation of nonadiabatic geometric quantum computation may be Rydberg atoms, since their internal states have very long coherence time and the Rydberg-mediated interaction facilitates the implementation of a two-qubit gate. Here, we propose a scheme of nonadiabatic geometric quantum computation based on Rydberg atoms, which combines the robustness of nonadiabatic geometric gates with the merits of Rydberg atoms.
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