4.5 Article

Protected two-qubit entangling gate with mechanical driven continuous dynamical decoupling

Journal

COMMUNICATIONS IN THEORETICAL PHYSICS
Volume 74, Issue 6, Pages -

Publisher

IOP Publishing Ltd
DOI: 10.1088/1572-9494/ac69c5

Keywords

silicon-vacancy color centers; high-fidelity entangling gate; mechanical driving modulation; quantum information processing

Funding

  1. Natural Science Foundation of Henan Province [222300420233]

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In this work, a high-fidelity phonon-mediated entangling gate in a hybrid mechanical system based on two silicon-vacancy color centers in diamond is proposed. By using a continuous dynamical decoupling approach and a mechanical driving field, the influence of spin decoherence on the gate is suppressed and the gate fidelity is significantly improved.
In this work, we propose a high-fidelity phonon-mediated entangling gate in a hybrid mechanical system based on two silicon-vacancy color centers in diamond. In order to suppress the influence of the spin decoherence on the entangling gate, we use a continuous dynamical decoupling approach to create new dressed spin states, which are less sensitive to environmental fluctuations and exhibit an extended T-2* spin dephasing time. The effective spin-spin Hamiltonian modified by the mechanical driving field and the corresponding master equation are derived in the dispersive regime. We show that in the presence of the mechanical driving field, the effective spin-spin coupling can be highly controlled. By calculating the entangling gate fidelity in the dressed basis, we find that once the mechanical field is turned on, the gate fidelity can be significantly improved. In particular, under an optimized spin-phonon detuning and a stronger Rabi frequency of the mechanical driving field, the two-qubit gate is capable of reaching fidelity exceeding 0.99. Moreover, by employing appropriate driving modulation, we show that a high-fidelity full quantum gate can be also realized, in which the initial and final spin states are on a bare basis. Our work provides a promising scheme for realizing high-fidelity quantum information processing.

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