Coupling two charge qubits via a superconducting resonator operating in the resonant and dispersive regimes

Chengxian Zhang; Guo Xuan Chan; Xin Wang; Zheng-Yuan Xue

doi:10.1103/PhysRevA.106.032608

Coupling two charge qubits via a superconducting resonator operating in the resonant and dispersive regimes

Chengxian Zhang, Guo Xuan Chan, Xin Wang^*, Zheng-Yuan Xue^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

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Abstract

A key challenge for semiconductor quantum-dot charge qubits is the realization of long-range qubit coupling and performing high-fidelity gates based on it. Here, we describe a different type of charge qubit formed by an electron confined in a triple-quantum-dot system, enabling single and two-qubit gates working in the dipolar and quadrupolar detuning sweet spots. We further present the form for the long-range dipolar coupling between the charge qubit and the superconducting resonator. Based on the hybrid system composed of the qubits and the resonator, we present two types of entangling gates: the dynamical iswap gate and holonomic entangling gate, which are operating in the dispersive and resonant regimes, respectively. We find that the fidelity for the iswap gate can reach a fidelity higher than 99% for the noise level typical in experiments. Meanwhile, the fidelity for the holonomic gate can surpass 98% if the anharmonicity in the resonator is large enough. Our proposal offers an alternative, useful way to build up high-fidelity quantum computation for charge qubits in the semiconductor quantum dot.

Original language	English
Article number	032608
Journal	Physical Review A
Volume	106
Issue number	3
Online published	12 Sept 2022
DOIs	https://doi.org/10.1103/PhysRevA.106.032608
Publication status	Published - Sept 2022

Funding

We thank Tao Chen for useful discussion. This work was supported by the Key-Area Research and Development Program of Guang Dong Province (Grant No. 2018B030326001), the National Natural Science Foundation of China (Grants No. 11905065, No. 11874156, and No. 11874312), the Research Grants Council of Hong Kong (Grant No. CityU 11303617), the Guang Dong Innovative and Entrepreneurial Research Team Program (Grant No. 2016ZT06D348), and the Guangxi Science Foundation (Grant No. AD22035186).

Publisher's Copyright Statement

COPYRIGHT TERMS OF DEPOSITED FINAL PUBLISHED VERSION FILE: Zhang, C., Chan, G. X., Wang, X., & Xue, Z-Y. (2022). Coupling two charge qubits via a superconducting resonator operating in the resonant and dispersive regimes. Physical Review A, 106(3), [032608]. https://doi.org/10.1103/PhysRevA.106.032608 The copyright of this article is owned by American Physical Society.

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title = "Coupling two charge qubits via a superconducting resonator operating in the resonant and dispersive regimes",

abstract = "A key challenge for semiconductor quantum-dot charge qubits is the realization of long-range qubit coupling and performing high-fidelity gates based on it. Here, we describe a different type of charge qubit formed by an electron confined in a triple-quantum-dot system, enabling single and two-qubit gates working in the dipolar and quadrupolar detuning sweet spots. We further present the form for the long-range dipolar coupling between the charge qubit and the superconducting resonator. Based on the hybrid system composed of the qubits and the resonator, we present two types of entangling gates: the dynamical iswap gate and holonomic entangling gate, which are operating in the dispersive and resonant regimes, respectively. We find that the fidelity for the iswap gate can reach a fidelity higher than 99% for the noise level typical in experiments. Meanwhile, the fidelity for the holonomic gate can surpass 98% if the anharmonicity in the resonator is large enough. Our proposal offers an alternative, useful way to build up high-fidelity quantum computation for charge qubits in the semiconductor quantum dot.",

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AU - Chan, Guo Xuan

AU - Wang, Xin

AU - Xue, Zheng-Yuan

PY - 2022/9

Y1 - 2022/9

N2 - A key challenge for semiconductor quantum-dot charge qubits is the realization of long-range qubit coupling and performing high-fidelity gates based on it. Here, we describe a different type of charge qubit formed by an electron confined in a triple-quantum-dot system, enabling single and two-qubit gates working in the dipolar and quadrupolar detuning sweet spots. We further present the form for the long-range dipolar coupling between the charge qubit and the superconducting resonator. Based on the hybrid system composed of the qubits and the resonator, we present two types of entangling gates: the dynamical iswap gate and holonomic entangling gate, which are operating in the dispersive and resonant regimes, respectively. We find that the fidelity for the iswap gate can reach a fidelity higher than 99% for the noise level typical in experiments. Meanwhile, the fidelity for the holonomic gate can surpass 98% if the anharmonicity in the resonator is large enough. Our proposal offers an alternative, useful way to build up high-fidelity quantum computation for charge qubits in the semiconductor quantum dot.

AB - A key challenge for semiconductor quantum-dot charge qubits is the realization of long-range qubit coupling and performing high-fidelity gates based on it. Here, we describe a different type of charge qubit formed by an electron confined in a triple-quantum-dot system, enabling single and two-qubit gates working in the dipolar and quadrupolar detuning sweet spots. We further present the form for the long-range dipolar coupling between the charge qubit and the superconducting resonator. Based on the hybrid system composed of the qubits and the resonator, we present two types of entangling gates: the dynamical iswap gate and holonomic entangling gate, which are operating in the dispersive and resonant regimes, respectively. We find that the fidelity for the iswap gate can reach a fidelity higher than 99% for the noise level typical in experiments. Meanwhile, the fidelity for the holonomic gate can surpass 98% if the anharmonicity in the resonator is large enough. Our proposal offers an alternative, useful way to build up high-fidelity quantum computation for charge qubits in the semiconductor quantum dot.

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Coupling two charge qubits via a superconducting resonator operating in the resonant and dispersive regimes

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GRF: Theory on Robust Manipulation of Silicon-based Spin Qubits

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Coupling two charge qubits via a superconducting resonator operating in the resonant and dispersive regimes

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GRF: Theory on Robust Manipulation of Silicon-based Spin Qubits

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