Improving Josephson junction reproducibility for superconducting quantum circuits: junction area fluctuation

Josephson superconducting qubits and parametric amplifiers are prominent examples of superconducting quantum circuits that have shown rapid progress in recent years. With the growing complexity of such devices, the requirements for reproducibility of their electrical properties across a chip have be...

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Bibliographic Details
Published in:arXiv.org 2022-10
Main Authors: Pishchimova, A A, Smirnov, N S, Ezenkova, D A, Krivko, E A, Zikiy, E V, Moskalev, D O, Ivanov, A I, Korshakov, N D, Rodionov, I A
Format: Article
Language:English
Subjects:
Circuits
Critical current (superconductivity)
Electrical junctions
Electrical properties
Josephson junctions
Nonuniformity
Parametric amplifiers
Qubits (quantum computing)
Reproducibility
Room temperature
Superconductivity
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Summary:Josephson superconducting qubits and parametric amplifiers are prominent examples of superconducting quantum circuits that have shown rapid progress in recent years. With the growing complexity of such devices, the requirements for reproducibility of their electrical properties across a chip have become stricter. Thus, the critical current \(I_c\) variation of the Josephson junction, as the most important electrical parameter, needs to be minimized. Critical current, in turn, is related to normal-state resistance the Ambegaokar-Baratoff formula, which can be measured at room temperature. Here, we focus on the dominant source of Josephson junction critical current non-uniformity junction area variation. We optimized Josephson junctions fabrication process and demonstrate resistance variation of \(9.8-4.4\%\) and \(4.8-2.3\%\) across \(22{\times}22\) \(mm^2\) and \(5{\times}10\) \(mm^2\) chip areas, respectively. For a wide range of junction areas from \(0.008\) \({\mu}m^2\) to \(0.12\) \({\mu}m^2\) we ensure a small linewidth standard deviation of \(4\) \(nm\) measured over 4500 junctions with linear dimensions from \(80\) to \(680\) \(nm\). The developed process was tested on superconducting highly coherent transmon qubits \((T_1 > 100\:{\mu}s)\) and a nonlinear asymmetric inductive element parametric amplifier.
ISSN:2331-8422