Digital Control of a Superconducting Qubit Using a Josephson Pulse Generator at 3 K

Overview

Journal PRX quantum

Publisher American Physical Society

Date 2023 Feb 2

PMID 36726390

Authors

L Howe

M A Castellanos-Beltran

A J Sirois

D Olaya

J Biesecker

P D Dresselhaus

S P Benz

P F Hopkins

Affiliations

Soon will be listed here.

Abstract

Scaling of quantum computers to fault-tolerant levels relies critically on the integration of energy-efficient, stable, and reproducible qubit control and readout electronics. In comparison to traditional semiconductor-control electronics (TSCE) located at room temperature, the signals generated by rf sources based on Josephson-junctions (JJs) benefit from small device sizes, low power dissipation, intrinsic calibration, superior reproducibility, and insensitivity to ambient fluctuations. Previous experiments to colocate qubits and JJ-based control electronics have resulted in quasiparticle poisoning of the qubit, degrading the coherence and lifetime of the qubit. In this paper, we digitally control a 0.01-K transmon qubit with pulses from a Josephson pulse generator (JPG) located at the 3-K stage of a dilution refrigerator. We directly compare the qubit lifetime , the coherence time , and the thermal occupation when the qubit is controlled by the JPG circuit versus the TSCE setup. We find agreement to within the daily fluctuations of ±0.5 s and ±2 s for and , respectively, and agreement to within the 1% error for . Additionally, we perform randomized benchmarking to measure an average JPG gate error of 2.1 × 10. In combination with a small device size ( 25 mm) and low on-chip power dissipation (≪100 W), these results are an important step toward demonstrating the viability of using JJ-based control electronics located at temperature stages higher than the mixing-chamber stage in highly scaled superconducting quantum information systems.

Citing Articles

AC metrology applications of the Josephson effect.

Benz S, Biesecker J, Burroughs C, Castellanos-Beltran M, Dresselhaus P, Flowers-Jacobs N Appl Phys Lett. 2024; 125(5).

PMID: 39534018 PMC: 11555766. DOI: 10.1063/5.0219991.

Nb/-Si/Nb-junction Josephson arbitrary waveform synthesizers for quantum information.

Olaya D, Biesecker J, Castellanos-Beltran M, Sirois A, Howe L, Dresselhaus P IEEE Trans Appl Supercond. 2023; 33(5).

PMID: 37720264 PMC: 10502609. DOI: 10.1109/tasc.2023.3249141.

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