Noise-Tolerant Superconducting Gates with High Fidelity

Pub Date : 2023-05-13 DOI:10.1007/s10946-023-10116-y

Junaid Khan, Javed Akram

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Abstract

We design two-qubit quantum gates by coupling two Transmon qubits with a capacitor and study the time-dependent dynamics of the qubit–qubit interaction for different inter-qubit interaction strengths in the presence of quantum noise. Particularly, we focus on three famous quantum gates, iSWAP, bSWAP, and CNOT. In this study, we investigate different types of noises, such as emission, absorption, and dephasing. Two-qubit gates, iSWAP and bSWAP, are modeled by direct variable coupling between two Transmon qubits. In addition, we construct the CNOT gate, using three qubits, where the two qubits are used for inputs and outputs, and the middle qubit acts as a tunable coupler between the two qubits. The middle qubit is needed for energy conservation; we called it a garbage bit, since we do not use it in logical operations. For the two input/output coupled qubits, direct variable capacitor coupling is also used. In view of the coupled Lindblad master equations, we study the time-dependent dynamics of our proposed quantum models. A significant impact of emission/absorption quantum noise can be seen on iSWAP, bSWAP, and CNOT gates, as compared to dephasing noise. Additionally, we also discuss the generation of entanglement for different scenarios with and without noises.

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高保真耐噪超导栅极

我们通过将两个Transmon量子比特与电容器耦合来设计双量子比特量子门，并研究了在量子噪声存在下不同量子比特相互作用强度下量子比特-量子比特相互作用的时间依赖动力学。我们特别关注三个著名的量子门，iSWAP, bSWAP和CNOT。在本研究中，我们研究了不同类型的噪声，如发射、吸收和消相。双量子比特门iSWAP和bSWAP是通过两个Transmon量子比特之间的直接变量耦合来建模的。此外，我们使用三个量子位构建了CNOT门，其中两个量子位用于输入和输出，中间量子位作为两个量子位之间的可调谐耦合器。中间量子位是能量守恒所必需的;我们称它为垃圾位，因为我们不在逻辑运算中使用它。对于两个输入/输出耦合量子位，也采用直接可变电容耦合。考虑到耦合的Lindblad主方程，我们研究了我们所提出的量子模型的时变动力学。与消相噪声相比，在iSWAP、bSWAP和CNOT门上可以看到发射/吸收量子噪声的显著影响。此外，我们还讨论了有噪声和无噪声情况下纠缠的产生。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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