Aluminum Josephson junction microstructure and electrical properties modified by thermal annealing.

Reproducibility of Al/AlO/Al Josephson junctions is a challenge for scaling up superconducting quantum processors. The frequency uncertainty of the transmon qubits arising from the fabrication process is attributed to deviations in the Josephson junction microstructure and electrical properties. Here, we present a solution for this problem using the post-fabrication Josephson junction thermal annealing process.

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. As such devices become more complex, the requirements for reproducibility of their electrical properties across a chip are being tightened. Critical current of the Josephson junction Ic is the essential electrical parameter in a chip.

Optimization of shadow evaporation and oxidation for reproducible quantum Josephson junction circuits.

The most commonly used physical realization of superconducting qubits for quantum circuits is a transmon. There are a number of superconducting quantum circuits applications, where Josephson junction critical current reproducibility over a chip is crucial. Here, we report on a robust chip scale Al/AlO/Al junctions fabrication method due to comprehensive study of shadow evaporation and oxidation steps.