Path-optimized nonadiabatic geometric quantum computation on superconducting qubits

Ding, Cheng-Yun; Ji, Li-Na; Chen, Tao; Xue, Zheng‐Yuan

doi:10.1088/2058-9565/ac3621

Cited by 20 publications

(6 citation statements)

References 59 publications

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“…Subsequently, Aharonov and Anandan [9] found that the adiabatic condition is not necessary, as long as certain requirements are met. This paved the way for geometric quantum computation based on the nonadiabatic evolution, i.e., nonadiabatic geometric quantum computation (NGQC), [10][11][12][13][14][15] with experimental demonstrations in many quantum systems, such as trapped ions, [16][17][18] NV center in diamond, [19,20] nuclear magnetic resonance, [21][22][23] and superconducting quantum circuits [24,25] , etc.…”

Section: Introductionmentioning

confidence: 99%

State‐Independent Geometric Quantum Gates via Nonadiabatic and Noncyclic Evolution

Chen,

Ji,

Xue

et al. 2023

Annalen der Physik

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Geometric phases are robust to local noises and the nonadiabatic ones can reduce the evolution time, thus nonadiabatic geometric gates have strong robustness and can approach high fidelity. However, the advantage of geometric phase has not been fully explored in previous investigations. Here,a scheme is proposed for universal quantum gates with pure nonadiabatic and noncyclic geometric phases from smooth evolution paths. In the scheme, only geometric phase can be accumulated in a fast way, and thus it not only fully utilizes the local noise resistant property of geometric phase but also reduces the difficulty in experimental realization. Numerical results show that the implemented geometric gates have stronger robustness than dynamical gates and the geometric scheme with cyclic path. Furthermore, it proposes to construct universal quantum gate on superconducting circuits, with the fidelities of single‐qubit gate and nontrivial two‐qubit gate can achieve 99.97% and 99.87%, respectively. Therefore, these high‐fidelity quantum gates are promising for large‐scale fault‐tolerant quantum computation.

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Section: Introductionmentioning

confidence: 99%

State‐Independent Geometric Quantum Gates via Nonadiabatic and Noncyclic Evolution

Chen,

Ji,

Xue

et al. 2023

Annalen der Physik

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“…The shortestpath NHQC scheme [31] based on a round evolution path also can accomplish the same gates with the single-loop NHQC scheme. Yet, the noise resistance varies greatly with different evolution paths [45][46][47], and thus, for a same gate, different evolution paths have different advantages in terms of gate fidelity and robustness. However, the previous schemes can not relax the freedom of path to complete a same gate, and thus fail to balance simultaneously the gate fidelity and robustness by choosing a suitable path.…”

Section: Introductionmentioning

confidence: 99%

Nonadiabatic Holonomic Quantum Computation via Path Optimization

Ji,

Liang,

Shen

et al. 2022

Preprint

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Nonadiabatic holonomic quantum computation (NHQC) is implemented by fast evolution processes in a geometric way to withstand local noises. However, the recent works of implementing NHQC are seneitive to the systematic noise/error. Here, we present a path-optimized NHQC scheme based on the non-Abelian geometric phase, and find that a geometric gate can be constructed by different evolution paths, which have different responses to systematic noises. Due to the flexibility of our scheme, we can select out a satisfying path that has the exceptional gate performance. Numerically simulations show our optimized scheme can greatly outperform the conventional single-loop scheme, in terms of both fidelity and robustness of the gates. In addition, we propose to implement our strategy on superconducting quantum circuits with decoherence-free subspace encoding with the experiment-friendly two-body exchange interaction. Therefore, we present a flexible NHQC scheme that is promising for the future robust quantum computation.

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“…Recently, many different NGQC protocols have been developed [13][14][15][16][17][18][19]; however, after experimental verification in var-ious quantum systems [20][21][22][23][24][25], it turns out that the advantages of geometric phase are compromised by local noises and the limitations of the protocol. To find better implementations, the orange-slice-shaped scheme [16][17][18][19] is proposed with simplified pulses, and the time and path optimal control techniques [26][27][28][29][30][31] are proposed to shorten the gate time and thus reducing the decoherence induced error. Meanwhile, when the Z error is the main error source, the dynamical decoupling method can be introduced [32][33][34].…”

Section: Introductionmentioning

confidence: 99%

Robust nonadiabatic geometric quantum computation by dynamical correction

Liang,

Xue

2022

Preprint

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Besides the intrinsic noise resilience property, nonadiabatic geometric phases are of the fast evolution nature, and thus can naturally be used in constructing quantum gates with excellent performance, i.e., the so-called nonadiabatic geometric quantum computation (NGQC). However, previous single-loop NGQC schemes are sensitive to the operational control error, i.e., the X error, due to the limitations of the implementation. Here, we propose a robust scheme for NGQC combining with the dynamical correction technique, which still uses only simplified pulses, and thus being experimental friendly. We numerically show that our scheme can greatly improve the gate robustness in previous protocols, retaining the intrinsic merit of geometric phases. Furthermore, to fight against the dephasing noise, due to the Z error, we can incorporate the decoherence-free subspace encoding strategy. In this way, our scheme can be robust against both types of errors. Finally, we also propose how to implement the scheme with encoding on superconducting quantum circuits with experimentally demonstrated technology. Therefore, due to the intrinsic robustness, our scheme provides a promising alternation for the future scalable fault-tolerant quantum computation.

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Path-optimized nonadiabatic geometric quantum computation on superconducting qubits

Cited by 20 publications

References 59 publications

State‐Independent Geometric Quantum Gates via Nonadiabatic and Noncyclic Evolution

State‐Independent Geometric Quantum Gates via Nonadiabatic and Noncyclic Evolution

Nonadiabatic Holonomic Quantum Computation via Path Optimization

Robust nonadiabatic geometric quantum computation by dynamical correction

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