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Optimized nonadiabatic holonomic quantum computation based on Förster resonance in Rydberg atoms

Shuai Liu, Jun-Hui Shen, Ri‐Hua Zheng, Yi‐Hao Kang, Zhi‐Cheng Shi, Jie Song, Yan Xia

2021Frontiers of Physics23 citationsDOI

Abstract

In this paper, we propose a scheme for implementing the nonadiabatic holonomic quantum computation (NHQC+) of two Rydberg atoms by using invariant-based reverse engineering (IBRE). The scheme is based on Förster resonance induced by strong dipole-dipole interaction between two Rydberg atoms, which provides a selective coupling mechanism to simply the dynamics of system. Moreover, for improving the fidelity of the scheme, the optimal control method is introduced to enhance the gate robustness against systematic errors. Numerical simulations show the scheme is robust against the random noise in control fields, the deviation of dipole-dipole interaction, the Förster defect, and the spontaneous emission of atoms. Therefore, the scheme may provide some useful perspectives for the realization of quantum computation with Rydberg atoms.

Topics & Concepts

HolonomicRydberg atomRydberg formulaDipolePhysicsQuantumRobustness (evolution)ComputationRealization (probability)Resonance (particle physics)Quantum mechanicsAtomic physicsChemistryComputer scienceAlgorithmMathematicsBiochemistryIonizationIonStatisticsGeneCold Atom Physics and Bose-Einstein CondensatesQuantum Information and CryptographyQuantum chaos and dynamical systems
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